Transcriptome Analysis Reveals Potential Antioxidant Defense

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Food and Beverage Chemistry/Biochemistry

Transcriptome Analysis Reveals Potential Antioxidant Defense Mechanisms in Antheraea pernyi in Response to Zinc Stress Yu Liu, Zhao-Zhe Xin, Jiao Song, Xiao-Yu Zhu, Qiuning Liu, Daizhen Zhang, Bo-Ping Tang, Chun-Lin Zhou, and Li-Shang Dai J. Agric. Food Chem., Just Accepted Manuscript • DOI: 10.1021/acs.jafc.8b01645 • Publication Date (Web): 05 Jul 2018 Downloaded from http://pubs.acs.org on July 6, 2018

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Transcriptome Analysis Reveals Potential Antioxidant Defense Mechanisms in

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Antheraea pernyi in Response to Zinc Stress

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Yu Liua,b,d,#, Zhao-Zhe Xina,d,#, Jiao Songc,#, Xiao-Yu Zhua, Qiu-Ning Liua,*, Dai-Zhen

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Zhanga, Bo-Ping Tanga,*, Chun-Lin Zhoua, Li-Shang Daib,*

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a

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Innovation Center for Coastal Bio-agriculture, Jiangsu Provincial Key Laboratory of

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Coastal Wetland Bioresources and Environmental Protection, School of Ocean and

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Biological Engineering, Yancheng Teachers University, Yancheng 224051, People's

Jiangsu Key Laboratory for Bioresources of Saline Soils, Jiangsu Synthetic

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Republic of China

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b

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People's Republic of China

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c

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Republic of China

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d

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Technology, Nanjing 210009, People's Republic of China

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* Corresponding author: Bo-Ping Tang, Li-Shang Dai, and Qiu-Ning Liu

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Tel/fax: +86 515 88233991

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E-mail: [email protected] (BP Tang), [email protected] (LS Dai),

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[email protected] (QN Liu).

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Address: Jiangsu Key Laboratory for Bioresources of Saline Soils, Jiangsu Synthetic

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Innovation Center for Coastal Bio-agriculture, Jiangsu Provincial Key Laboratory of

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Coastal Wetland Bioresources and Environmental Protection, School of Ocean and

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Biological Engineering, Yancheng Teachers University, Yancheng 224051, People's

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Republic of China.

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#

School of Pharmaceutical Sciences, Wenzhou Medical University, Wenzhou 325035,

College of Life Science, Anhui Agricultural University, Hefei 230036, People's

College of Biotechnology and Pharmaceutical Engineering, Nanjing University of

These authors contributed equally to this work.

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ABSTRACT

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The growth and development of the Chinese oak silkworm, Antheraea pernyi (A.

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pernyi), is strongly influenced by environmental conditions, including heavy metal

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pollution. An excess of heavy metals causes cellular damage through the production

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of free-radicals reactive oxygen species. In this study, transcriptome analysis was

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performed to investigate global gene expressions when A. pernyi was exposed to zinc

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infection. With RNA sequencing (RNA-Seq), a total of 25,795,510 and 38,158,855

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clean reads were obtained from zinc-treated and control fat bodies libraries,

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respectively. We identified 2,399 differentially expression genes (DEGs) (1,845

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up-regulated and 544 down-regulated genes) in zinc-treated library. Further, Kyoto

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Encyclopedia of Genes and Genomes (KEGG) enrichment analysis revealed that these

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DEGs were related to peroxisome pathway that was associated with antioxidant

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defense. Our results suggest that fat bodies of A. pernyi constitute a strong antioxidant

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defense against heavy metal contamination.

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KEYWORDS: Antheraea pernyi; antioxidant mechanisms; heavy metals; zinc;

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transcriptome

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INTRODUCTION

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A. pernyi, one of the most important wild silkworm species in economy, produce

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thousands of tons of tussah silk per year and thus play a vital role in the textile

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industry.1,2 A. pernyi diverged from dipterans 240 million years ago and was

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domesticated in China in the 18th Century.3,4 To date, its breeding ground has covered

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more than 700,000 acres, mainly distributing in China, Japan, India, and southeast

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Asian countries.5 It has been reported that 90% of the world’s tussah cocoons and

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silks originate from China, which provides the suitable habitat for silkworm survival.6

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A. pernyi is an completely metamorphic insect with a diapause state and its life

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history can be divided into four stages: egg, larva, pupa, and moth. The pupae of A.

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pernyi contains all the essential amino acids and are considered to be a source of

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high-quality dietary protein.7 Furthermore, A. pernyi is now used as a model organism

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for a variety of research purposes because of its ease of rearing and experimental

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manipulation compared with other lepidopteran insects. However, the health and

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vigor of A. pernyi are threatened by numerous parasites and pathogens, including

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viruses,8 mites,9 bacteria10 and protoza.11 In addition, the growth and development of

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larva are also strongly affected by environmental conditions, including heavy metal

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pollution, climate, foliage and diseases.12

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Heavy metals are natural compounds found in soil, rock, air, water and living

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organisms and are essential micronutrients for growth and development of organisms,

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such as copper and zinc. Heavy metals, however, are also serious pollutants and have

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led to a worldwide environmental problem.13,14 These substances pose serious threats

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to human health and global ecosystems via various ways, including biogeochemical

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cycle, microbial activity and human activities.15,16 An excess of heavy metals in cells

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cause oxidative stress because of the formation of free radicals and reactive oxygen

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species (ROS).17,18 ROS can be produced in all aerobic organisms due to the

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mandatory dependence of oxidative metabolism on the ground-state of molecular

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oxygen.19 Insects have evolved an array of antioxidant defense systems to keep

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themselves from oxidative damages.20 Superoxide dismutase (SOD), catalase (CAT),

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glutathione peroxide (GSH-PX) and glutathione reductase (GR) play vital roles in

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protecting organisms from endogenous ROS, and they can clean ROS to avoid

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oxidative damage.19 In addition, glutathione S-transferases (GSTs) are involved in the

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metabolism

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antioxidant.19,21 These antioxidant enzymes are also thought to be essential

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components of insect antioxidant defense systems.22 In recent years, there have been

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several reports of antioxidant enzymes present in different species of Lepidopteran

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insect larvae. 23-25 However, to our knowledge, antioxidant enzymes involved in the

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response to zinc challenge have not been reported. Zinc, the second most abundant

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metal in organisms, has been identified as a contaminant of concern in Japan and

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selected as a model toxicant.26

of

polycyclic

hydrocarbons,

pesticides

and

the

endogenous

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Transcriptome sequencing is widely used for genome analysis and functional

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gene identification, aiding our understanding of genetic responses of hosts to heavy

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metals and the molecular mechanisms of antioxidant defense systems. In the present

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study, transcriptome analysis was conducted on A. pernyi fat bodies using an Illumina

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sequencing platform to identify functional genes. As an important organ, insect fat

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body is equivalent to the liver and adipose of vertebrates, and plays key roles in

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metabolic activities including nutrient supply and intermediary metabolism.27-29 The

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differentially expressed genes (DEGs) were identified in different functional

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databases and the results were annotated to investigate their potential functions. The

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findings provide a further understanding of antioxidant mechanisms in A. pernyi.

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MATERIALS AND METHODS

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Insect collection and challenge experiments

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Individuals of A. pernyi were collected from the Sericultural Research Institute of

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Henan and reared on oak leaves until pupation. The pupae were kept at room

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temperature in advance, and then were divided into two groups (n = 3 per group): the

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zinc exposure group and the control group. The former was treated with 10 µL ZnCl2

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solution while the latter was treated with 10 µL phosphate buffered saline (PBS)

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solution. After 24 h infection, the fat bodies of these two groups were collected,

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labeled and then stored in liquid nitrogen for RNA extraction.

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Total RNA isolation, cDNA library construction, and sequencing

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Library construction and RNA-Seq were performed at Beijing BioMarker

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Technologies (Beijing, China). Total RNA from fat bodies tissue was isolated with

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TRIzol Reagent (Invitrogen, USA) according to the manufacturer’s instructions. After

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extraction, RNA degradation and contamination were monitored on 1% agarose gels.

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In addition, RNA purity, concentration and integrity were evaluated with NanoDrop

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(Implen, Westlake Village, CA, U.S.A.), Qubit 2.0 (Life Technologies, Carlsbad, CA,

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U.S.A.), and Agilent 2100 (Agilent Technologies, Santa Clara, CA, U.S.A)

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instruments, respectively.

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Briefly, mRNA was purified from total RNA using poly-T oligo-attached

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magnetic beads, and mRNA fragmentation was carried out using divalent cations

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under elevated temperature in NEBNext First Strand Synthesis Reaction Buffer (5×).

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First-strand cDNA was synthesized using random hexamer primers and M-MuLV

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reverse transcriptase (RNase H-). Subsequently, second-strand cDNA was synthesized

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using DNA polymerase I and RNase H. These double-stranded cDNA fragments

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underwent end repair, addition of a single ‘A’ base, and ligation of adapters, and

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adaptor-modified fragments were isolated by gel purification and amplified by PCR to

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create the final cDNA library.

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Transcriptome Sequencing of the cDNA libraries derived from the zinc exposure

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and control groups was performed on Illumina HiSeq 2500 platform, which is based

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on synthesis technology. Before proceeding with the analysis, it is necessary to

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confirm that the quality of the reads was sufficient to ensure the accuracy of the

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sequence assembly and subsequent analysis. The de novo assembly of RNA-Seq was

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performed using Trinity software.30

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Functional unigenes annotation and classification

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The functional unigenes were annotated based on the following databases: NCBI

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non-redundant protein/nucleotide sequences (Nr/Nt, http://www.ncbi.nlm.nih.gov/, E

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values cutoff ≤ 1e-5),31 Protein family (Pfam, https://pfam.sanger.ac.uk/, E values

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cutoff ≤ 1e-5),32 euKaryotic Ortholog Groups/Clusters of Orthologous Groups of

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proteins (KOG/COG, https://www.ncbi.nlm.nih.gov/COG/, E values cutoff 1e-3),33

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Swiss-Prot (http://www.ebi.ac.uk/uniprot, E values cutoff ≤ 1e-5),34 Kyoto

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Encyclopedia of Genes and Genomes (KEGG, http://www.genome.jp/kegg/, E values

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cutoff ≤ 1e-10),35 and Gene Ontology (GO, http://www.geneontology.org/, E values

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cutoff ≤ 1e-6). The Blast2GO program36 was used to assign GO annotations to three

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main categories (molecular function, cellular component and biological process)

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based on the Nr annotation (E values cutoff ≤ 1e-6). Then, GO functional classification

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was performed with WEGO software37 and the KEGG pathways of unigenes were

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analyzed based on BLASTX hits against the KEGG database.

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Quantification of gene expression levels and DEG screening

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The gene expression levels were estimated by RNA-Seq by Expectation

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Maximization (RSEM) for each sample.38 Clean data were mapped back onto the

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assembled transcriptome using TopHat software (version 2.1.1), and the read count

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for each gene was obtained from the mapping results. Calculation of unigene

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expression was measured by fragment per kilobase of exon per million fragments

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mapped (FPKM) based on the number of uniquely mapped reads.39 The longest

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transcript was selected to calculate the FPKM when a gene has more than one

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alternative transcripts.40 Differential expression analysis of two groups was performed

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using the DESeq R package to screen out the DEGs. To correct for multiple testing,

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the false discovery rate (FDR) was calculated to adjust the threshold of p-value. DEGs

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were defined as genes with FDR values < 0.01, and |log2(foldchange)| > 1 (minimal

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2-fold difference in expression).41

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GO and KEGG enrichment analyses

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GO enrichment analysis of DEGs was implemented using the topGO R packages

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based on the Kolmogorov–Smirnov test.42 KEGG, as a database resource, was used to

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interpret high-level functions and utilities of the cell, the organism and the ecosystem

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based on molecular-level information.43 Furthermore, KOBAS software was used to

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test the statistical significance of DEG enriched in KEGG pathways.44

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RESULTS AND DISCUSSION

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Transcriptome sequence and assembly

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The transcriptome of A. pernyi was assembled de novo using paired-end raw reads

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generated by the Illumina HiSeq2500. After filtering out redundant and short reads,

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25,795,510 clean reads were obtained in the control (PBS-treated) group and

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38,158,855 in the zinc exposure group (Table 1). The Illumina guidelines were

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applied for data quality assessment and the result showed that more than 92% of the

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sequencing data for each sample were found to have a quality score of Q30. The GC

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counts for the control group and the zinc exposure group were 43.12% and 43.07%,

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respectively. Besides, 20,423,257 (79.17%) and 29,020,615 (76.05%) clean reads

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were respectively obtained from two groups, which successfully matched to the A.

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pernyi genome. According to the statistics, 65.80% of the reads were uniquely

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mapped to the genome for the control group and 71.38% for the zinc exposure group.

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Furthermore, 16.89% and 28.62% of the reads, respectively, were multiply mapped to

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the genome for the control group and the zinc exposure group. Most unigenes are

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distributed at 200-300 bp, 300-500 bp, and 500-1000 bp (Fig. 1). These results

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demonstrated that the sequencing quality was relatively high, which means

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the unigenes were suitable for subsequent annotation analysis.

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Functional annotation and classification

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To analyze the gene function information, unigenes were annotated using seven

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databases (Nr, Swiss-Prot, COG, KOG, eggNOG, GO and KEGG). In total, 22,620 of

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unigenes were matched in Nr. In Nr annotation, 22,543 unigenes were matched to

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multiple species genomes, including Bombyx mori (39.48%), Danaus plexippus

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(16.92%), Tribolium castaneum (11.29%), Ceratitis capitata (1.66%), Papilio xuthus

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(1.30%), Dendroctonus ponderosae (1.20%), Manduca sexta (0.84%), Acanthamoeba

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castellanii (0.73%), Acyrthosiphon pisum (0.71%), Nematostella vectensis (0.65%),

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and others (25.02%) (Table 2).

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GO classification is a standardized system for categorizing genes and gene

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products across species and it was performed using the Blast2GO program. On the

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basis of the functional annotation, 12,602 unigenes were classified into three main GO

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categories: biological process, cellular component and molecular function. These

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unigenes were further divided into 57 subcategories as shown in Figure 2 and Table 3.

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Among these subcategories, 20, 19, and 18 of them were clustered in the biological

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process, cellular component and molecular function categories, respectively. In the

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biological process category, the most abundant groups were “metabolic process” (GO:

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0008152) with 7,861 unigenes and “cellular process” (GO: 0009987) with 6,377

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unigenes. Within the cellular component category, most of the unigenes were assigned

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to the terms “cell” (GO 0005623) and “cell part” (GO 0044464), which involved in

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the basic structural and functional unit of all organisms.45 However, among sequences

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categorized as molecular function, 6,542 unigenes were predicted to have “catalytic

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activity” (GO:0003824) and 6,412 unigenes were predicted to have “binding” (GO:

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0005488) activity. These results indicate that the annotated unigenes were most often

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associated with various types of biological process. According to the GO analysis,

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immune-related genes were enriched in the biological process categories, with many

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unigenes assigned to the subcategories “immune system process” (GO:0002376) and

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“response to stimulus” (GO:0050896). A total of 1,475 and 138 unigenes were

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assigned to the subcategories “immune system process” and “response to stimulus”,

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respectively. In addition, 70 unigenes were assigned to “antioxidant activity”

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(GO:0016209).

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The KOG database is used to evaluate the completeness of transcriptomes and the

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effectiveness of the annotation processes. In this study, 14,961 unigenes were

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annotated and classified into 25 KOG categories (Fig. 3 and Table 4). Among the

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functional classes, the category with the greatest number of unigenes was “general

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function prediction only” (R, 3,115, 20.82%), followed by “signal transduction

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mechanisms” (T, 1,692, 11.31%), and “posttranslational modification, protein

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turnover, chaperones” (O, 1,517, 10.14%). The three categories “cell motility”,

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“nuclear structure”, and “extracellular structures” contained the lowest number of

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unigenes, accounting for 36, 69, and 124 unigenes, respectively. In total, 169 unigenes

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were assigned to the cluster of “defense mechanisms”, indicating that these unigenes

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might be involved in antioxidant defense in A. pernyi. Additionally, the functions of

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890 unigenes were unknown.

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Identification and analysis of DEGs

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To identify genes in A. pernyi whether or not expressed differently in response to zinc

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exposure, the numbers of clean reads from the transcriptomes of the control and zinc

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exposure groups were mapped back, the read counts compared, and the gene

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expression levels estimated. Pearson correlation analysis revealed a significant

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difference between the two groups (r2 = 0.4813; Fig. 4). Differential expression

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analysis revealed 2,399 significant DEGs (1,845 upregulated and 554 downregulated)

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in the zinc exposure group compared with the control group, with FDR 1 (Fig. 5).

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GO and KEGG enrichment analysis of DEGs

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To further investigate the function of DEGs, unigenes were annotated using different

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functional databases: 1,004 in COG, 655 in GO, 851 in KEGG, 1,211 in KOG, 1,336

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in Pfam, 968 in Swiss-Prot, 1,462 in eggNOG and 1,397 in Nr. According to GO

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enrichment analysis using Blast2GO with a correct p-value