Abstract

Background

   Microtus fortis is a non-permissive host of Schistosoma japonicum. It
   has natural resistance against schistosomes, although the precise
   resistance mechanisms remain unclear. The paucity of genetic
   information for M. fortis limits the use of available immunological
   methods. Thus, studies based on high-throughput sequencing technologies
   are required to obtain information about resistance mechanisms against
   S. japonicum.

Results

   Using Illumina single-end technology, a de novo assembly of the M.
   fortis transcriptome produced 67,751 unigenes with an average length of
   868 nucleotides. Comparisons were made between M. fortis before and
   after infection with S. japonicum using RNA-seq quantification
   analysis. The highest number of differentially expressed genes (DEGs)
   occurred two weeks after infection, and the highest number of
   down-regulated DEGs occurred three weeks after infection.
   Simultaneously, the strongest pathological changes in the liver were
   observed at week two. Gene ontology terms and pathways related to the
   DEGs revealed that up-regulated transcripts were involved in
   metabolism, immunity and inflammatory responses. Quantitative real-time
   PCR analysis showed that patterns of gene expression were consistent
   with RNA-seq results.

Conclusions

   After infection with S. japonicum, a defensive reaction in M. fortis
   commenced rapidly, increasing dramatically in the second week, and
   gradually decreasing three weeks after infection. The obtained M.
   fortis transcriptome and DEGs profile data demonstrated that natural
   and adaptive immune responses, play an important role in M. fortis
   immunity to S. japonicum. These findings provide a better understanding
   of the natural resistance mechanisms of M. fortis against schistosomes.

Electronic supplementary material

   The online version of this article (doi: 10.1186/1471-2164-15-417)
   contains supplementary material, which is available to authorized
   users.

   Keywords: Microtus fortis, Schistosoma japonicum, Non-permissive host,
   RNA-seq

Background

   Schistosome infections occur in over 70 tropical and subtropical
   countries, with 200 million individuals infected, resulting in 200,000
   human deaths annually [[37]1]. The pathology of chronic infections with
   S. japonicum includes granuloma formation in the liver, periportal
   fibrosis, portal hypertension and the formation of vascular shunts
   [[38]2]. Serious schistosomiasis reduces the ability of humans to work
   and impedes the development of agriculture and livestock. It is crucial
   to control schistosomiasis transmission, improve the level of public
   health knowledge and increase income in agriculture and livestock. At
   present, praziquantel (PZQ) is the only safe, cheap and effective drug
   against human schistosome species. However, massive administration of
   PZQ in endemic areas has raised serious concerns regarding the
   development of parasite resistance to PZQ [[39]3]. Isolates of S.
   mansoni from patients in Kisumu, Kenya, were shown to have lower
   susceptibility to PZQ [[40]4]. Clarifying the immune mechanisms of S.
   japonicum infection is an important foundation to screen effective
   vaccine candidates and novelty drugs against schistosomiasis.

   The reed vole (Microtus fortis) has been identified as a non-permissive
   host of S. japonicum that has a natural resistance mechanism against
   schistosomes [[41]5–[42]8]. Several studies of the resistance of M.
   fortis to S. japonicum have been conducted. Eosinophils, neutrophils,
   macrophages and serum antibodies are thought to be involved in
   resistance [[43]9] and nitric oxide, albumin, E77, KPNA2, HSP90 were
   found to be resistance-associated proteins [[44]9–[45]11]. It has been
   suggested that apoptosis might be employed by M. fortis for eliminating
   schistosomes [[46]12]. This study aimed to provide new suggestions to
   control the spread of schistosomiasis and to further elucidate the
   resistance mechanisms against schistosomes in M. fortis.

   Because M. fortis is a new experimental animal model, biological
   information about it is very limited. To date, only 328 nucleotides, 68
   ESTs and 26 genes of M. fortis are accessible from all NCBI databases,
   and no monoclonal antibodies specific for these markers are
   commercially available. It is therefore extremely difficult to study
   resistance mechanisms using immunological techniques, such as flow
   cytometry, Western blot or microarrays. Due to the high cost of genome
   sequencing, transcriptome sequencing is a useful tool to obtain
   biological information and to discover and identify new genes of M.
   fortis. The next-generation sequencing (NGS) based RNA-Seq technique
   has been widely used for de novo transcriptome sequencing assembly,
   discovery of novel genes and the investigation of gene expression in
   many non-model organisms [[47]13]. It is therefore suitable for the
   identification of potential resistance-related genes in M. fortis.

   In this study, we sequenced the M. fortis transcriptome using Illumina
   technology and demonstrated the suitability of short-read sequencing
   for the de novo assembly and annotation of genes expressed in a
   eukaryote without prior genome information. In addition, we compared
   the gene expression profiles of M. fortis up to four weeks after
   infection with schistosomes by using an RNA-Seq quantification
   expression system. The assembled and annotated transcriptome sequences
   and gene expression profiles showed that natural and adaptive immune
   responses, such as Toll-like receptors (TLR), natural killer (NK) cell
   activation and IgG and IgE, play important roles against S. japonicum
   infections. These data provide a valuable resource for the analysis of
   resistance genes of M. fortis against S. japonicum.

Results

Pathological changes in the liver

   After infection with S. japonicum for 2–3 weeks, several white nodules
   were observed in the liver of M. fortis, which disappeared 3–4 weeks
   after infection. The liver was then restored to its original color,
   structure and texture. This phenomenon was also observed by Shao
   [[48]14] and it is speculated that these white nodules are induced by a
   schistosomulum [[49]15]. Some reports described many worm-granulomas
   detected in the liver of M. fortis, schistosomula were impaired by
   inflammatory cells surrouding [[50]15, [51]16]. Conversely, no changes
   occurred in the livers of BALB/c mice (which are permissive hosts for
   S. japonicum) after the first four weeks of infection. High numbers of
   liver granulomas were observed after the deposition of eggs in the
   liver of mice (Figure [52]1).

Figure 1.

   Figure 1
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   Pathological liver changes. A: Liver of M. fortis after two weeks of
   infection. B: Liver of M. fortis after four weeks of infection. C:
   Liver of BALB/c mouse after two weeks of infection. D: Liver of BALB/c
   mouse after four weeks of infection. E: Liver of BALB/c mouse after six
   weeks of infection.

Illumina sequencing and de novo transcriptome assembly

   To obtain an overview of an M. fortis gene expression profile, cDNA
   from the liver of M. fortis was generated and sequenced using the
   Illumina sequencing platform. After removing adaptors and low quality
   reads, 134,985,444 clean reads were obtained from sequencing. The GC
   content and Q20 were 48.98% and 98.03%, respectively. These reads were
   assembled with the Trinity software. After clustering using the TGICL
   program, we obtained 166,501 contigs and 67,751 unigenes (mean length:
   868 nt) with an N50 of 1,631 nt (Additional file [54]1: Table S1).
   Simultaneously, an abundance of unannotated unigenes was generated in
   our study, which might represent a specific gene pool of interest for
   further M. fortis studies.

Function annotation and classification of assembled transcripts

   To annotate these unigenes, we searched the reference sequences using
   BLASTx against the NCBI non-redundant (nr) and Swiss-Prot protein
   databases with a cut-off E-value of 10^-5. A total of 33,384 (49.27% of
   all distinct sequences) and 31,001 (45.76% of all distinct sequences)
   were obtained as significant hits using the respective databases
   (Additional file [55]2: Table S2). However, there were still many
   sequences (11,815, 17.44%) without BLASTx hits. These sequences might
   be new genes or non-coding RNA sequences. Among these, 55,936 unigenes
   (82.56% of 67,751 unigenes) were annotated with the NR, NT, Swiss-Prot,
   Kyoto Encyclopedia of Genes and Genomes (KEGG), COG and gene ontology
   (GO) by BLAST databases, and functional bioinformatics analyses. The
   annotation results show that the species Cricetulus griseus (44.5%),
   Mus musculus (22.1%), and Rattus norvegicus (14.0%) were highly
   homologous with M. fortis (Figure [56]2).

Figure 2.

   Figure 2
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   Homology analysis of M. fortis transcriptome. All distinct gene
   sequences that had BLAST annotations within the nr database with a
   cut-off E-value ≤ 10–5 were analyzed for: A: E-value distribution; B:
   similarity distribution; C: species distribution.

   To evaluate our transcriptome library, we searched the annotated
   sequences for the genes involved in COG classifications [[58]17].
   Unigenes were aligned to the COG database to predict and classify
   possible functions. A total of 24,238 sequences were functionally
   classified into 25 COG categories. The largest number of unigenes
   focused on “the general function of prediction” class, the
   second-largest groups were in the “replication, recombination and
   repair” and “transcription” classes, followed by “cell cycle control,
   cell division, chromosome partitioning”, “chromosome partitioning”,
   “posttranslational modification” and “protein turnover” (Figure [59]3).
   To further evaluate the completeness of the de novo assembly
   transcriptome and predict possible functions, a GO functional
   annotation was used to classify the functions of the predicted M.
   fortis genes. In total, 27,010 sequences could be categorized into 60
   functional groups in the three main categories of “cellular component”,
   “molecular function” and “biological process”. In these categories the
   number of unigenes categorized as “biological process” accounted for
   nearly 40%. This dominant processes were involved in developmental
   biology, biosynthesis, metabolism, stimulus–response and signal
   transduction. A few genes were associated with terms such as “cell
   killing”, “nucleoid”, “chemoattractant activity”, “chemorepellent
   activity”, “receptor regulator activity” and “translation regulator
   activity” (Figure [60]4).

Figure 3.

   Figure 3
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   COG function classification of assembled M. fortis transcripts.

Figure 4.

   Figure 4
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   Gene ontology classification of assembled M. fortis transcripts.

   The KEGG is a bioinformatics resource for linking genomes to life and
   the environment and for understanding high-level gene functions in
   terms of networks of the biological system
   ([63]http://www.genome.jp/kegg/). In our research, 23,898 unigenes were
   mapped to 258 KEGG pathways (Additional file [64]3: Dataset S1). Among
   them, “metabolic pathways” (2432 unigenes, 10.18% of sequences),
   “pathways in cancer” (993 unigenes, 4.16% of sequences 4.16%) and
   “regulation of actin cytoskeleton” (923 unigenes, 3.86% of sequences)
   were dominant. In 258 KEGG pathways, there were 20 pathways involved in
   immune and inflammatory responses (Table [65]1), such as endocytosis
   (2.87%), MAPK signaling pathway (2.62%), chemokine signaling pathway
   (2.12%), wnt signaling pathway (1.8%) and Fc gamma R-mediated
   phagocytosis (1.74%). The gene catalog provided a comprehensive
   understanding of the gene transcription profiles of M. fortis, and it
   provided a valuable foundation for screening differential expression
   genes after infection with S. japonicum.

Table 1.

   Pathways of de novo transcriptome involved in immunity and inflammation
   responses
   Pathway All genes with pathway annotation (23898) Pathway ID
   Endocytosis 685 (2.87%) ko04144
   MAPK signaling pathway 627 (2.62%) ko04010
   Chemokine signaling pathway 507 (2.12%) ko04062
   Wnt signaling pathway 430 (1.8%) ko04310
   Fc gamma R-mediated phagocytosis 416 (1.74%) ko04666
   Cytokine-cytokine receptor interaction 328 (1.37%) ko04060
   Leukocyte transendothelial migration 327 (1.37%) ko04670
   JAK-STAT signaling pathway 302 (1.26%) ko04630
   NF-kappa B signaling pathway 288 (1.21%) ko04064
   T cell receptor signaling pathway 256 (1.07%) ko04660
   B cell receptor signaling pathway 254 (1.06%) ko04662
   Complement and coagulation cascades 253 (1.06%) ko04610
   NK cell-mediated cytotoxicity 238 (1%) ko04650
   Notch signaling pathway 231 (0.97%) ko04330
   TGF-beta signaling pathway 225 (0.94%) ko04350
   Apoptosis 216 (0.9%) ko04210
   TLR signaling pathway 203 (0.85%) ko04620
   NOD-like receptor signaling pathway 185 (0.77%) ko04621
   Antigen-processing and presentation 136 (0.57%) ko04612
   Intestinal immune network for IgA production 54 (0.23%) ko04672
   [66]Open in a new tab

DEGs involved in the response to infection with S. japonicum

   To investigate the changes in gene expression and understand the
   critical genes in M. fortis responses to S. japonicum, we used RNA-Seq
   technology to study transcriptional changes. Clean reads of M. fortis
   that were infected with S. japonicum from 1–4 weeks were respectively
   mapped to the de novo assembly transcriptome reference sequences of M.
   fortis using SOAP aligner/SOAP2 [[67]18]. The clean reads mapped to the
   genes were approximately 86.93% to 87.70% in the four respective
   libraries, in which approximately 69.13% to 76.84% reads were perfectly
   matched (Table [68]2). The expression levels of the unigenes were
   calculated using the RPKM algorithm. The RPKM values can be directly
   used for comparing the differences in gene expression among samples. We
   used “FDR ≤ 0.001 and the absolute value of log[2] ratio ≥ 2” as
   threshold to judge the significance of gene expression difference. From
   these results, the amounts of DEGs were detected at different time
   points pre- and post-infection (Figure [69]5). Based on RNA-Seq
   (quantification) analysis, it was shown that the number of up-regulated
   genes at the second week after infection was 1,354, which was much
   higher than that at other weeks. Compared to the second week after
   infection, the numbers of down-regulated genes at the third and fourth
   weeks after infection were 1,202 and 1,304, respectively. A high number
   of DEGs in the liver of M. fortis overlapped at different points after
   infection (Figure [70]6).

Table 2.

   DGE sequencing statistics
   Map to Gene Total reads Total BasePairs Total mapped Reads Perfect
   match ≤ 2 bp mismatch Unique match Multi-position match Total unmapped
   reads
   M. fortis 0w Number 14108810 6.91E + 08 12386868 10841524 1545344
   8899796 3487072 1721942
   Percentage 100.00% 100.00% 87.80% 76.84% 10.95% 63.08% 24.72% 12.20%
   M. fortis 1w Number 14541376 7.13E + 08 12661913 10539814 2122099
   9081999 3579914 1879463
   Percentage 100.00% 100.00% 87.08% 72.48% 14.59% 62.46% 24.62% 12.92%
   M. fortis 2w Number 14414203 7.06E + 08 12569395 10659905 1909490
   8823147 3746248 1844808
   Percentage 100.00% 100.00% 87.20% 73.95% 13.25% 61.21% 25.99% 12.80%
   M. fortis 3w Number 14029434 6.87E + 08 12263700 9975484 2288216
   8773301 3490399 1765734
   Percentage 100.00% 100.00% 87.41% 71.10% 16.31% 62.53% 24.88% 12.59%
   M. fortis 4w Number 14093913 6.91E + 08 12252516 9743528 2508988
   8705359 3547157 1841397
   Percentage 100.00% 100.00% 86.93% 69.13% 17.80% 61.77% 25.17% 13.07%
   [71]Open in a new tab

Figure 5.

   Figure 5
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   Overview of differential expression at different points after infection
   . In a pairwise comparison (denoted as MfA-VS-MfA1W, for example), the
   former (MfA) was considered as the control, and the latter (MfA1W) was
   considered as the treatment. MfA, M. fortis before infection; MfA1W: M.
   fortis after infection for 1 week; MfA2W: M. fortis after infection for
   2 weeks; MfA3W: M. fortis after infection for 3 weeks; MfA4W: M. fortis
   after infection for 4 weeks.

Figure 6.

   Figure 6
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   Overlap between numbers of DEGs responding to S. japonicum . MfA1W: M.
   fortis after infection for 1 week; MfA2W: M. fortis after infection for
   2 weeks; MfA3W: M. fortis after infection for 3 weeks; MfA4W: M. fortis
   after infection for 4 weeks.

GO and pathway functional enrichment analysis of DEGs

   To understand the functions of the DEGs, we performed GO functional
   enrichment and KEGG pathway analyses using a hypergeometric
   distribution model. When comparing M. fortis samples before infection
   and four weeks after infection, the terms “cell periphery”,
   “extracellular space”, “plasma membrane”, “external side of plasma
   membrane”, “extracellular region”, “cell surface” and “cytoplasm”
   showed the most significant differences (Additional files [74]4, [75]5,
   [76]6 and [77]7: Datasets S2, S3, S4, S5).

   By analyzing the statistically enriched GO function related to the
   DEGs, it was revealed that the most significant and most frequently
   enriched terms for up-regulated transcripts after infection were
   inflammatory- and immunity-correlated genes. The first class included
   pattern recognition receptors (PRRs), such as mannose-binding lectin
   (MBL, K03991), C-reactive protein (CRP, [78]K01672), scavenger receptor
   (SR, GO:0005044), complement receptor (CR, GO:0002430) and TLRs
   (GO:0002755, GO:0006954, GO:0034162, GO:0034134). The second class
   consisted of cytokines and complement-related unigenes, such as
   interferon-gamma (IFN-γ)-related unigenes (GO:0003924, GO:0000975,
   GO:0005515, GO:0003723), tumor necrosis factor (TNF)-related unigenes
   (GO:0005164, GO:0033209, GO:0005031, GO:0043120) and complement-related
   unigenes (GO:0006956, GO:0006957, GO:0006958, GO:0001851). The third
   class was comprised of lymphocyte activation-related molecules, such as
   T- and B lymphocyte-related unigenes (GO:0003823, GO:0015643,
   GO:0005488, GO:0019901, GO:0005068) and macrophage-related unigenes
   (GO:0008603, GO:0043621, GO:0070891).

   Pathways related to the DEGs related to inflammatory and immunity
   responses were “antigen-processing and presentation”, “intestinal
   immune network for IgA production”, “natural killer cell-mediated
   cytotoxicity”, “B cell receptor signaling pathway”, “MAPK signaling”,
   “NF-kappa B”, “JAK-STAT signaling”, “Toll-like receptor signaling”,
   “TGF-beta signaling pathway”, “wnt signaling pathway” and “complement
   and coagulation cascades” (Table [79]3).

Table 3.

   Pathway of RNA-seq involved in immunity and inflammation responses
   after infection for four weeks
   Pathway DEGs with pathway annotation All genes with pathway annotation
   1st w (700) 2nd w (946) 3rd w (665) 4th w (432) 1st w 2nd w 3rd w 4th w
   Jak-STAT signaling 15 (2.14%) 22 (2.33%) 13 (1.95%) 5 (1.16%) 577
   (1.51%) 577 (1.51%) 577 (1.51%) 577 (1.51%)
   MAPK signaling 26 (3.71%) 29 (3.07%) 16 (2.41%) 9 (2.08%) 1058 (2.76%)
   1058 (2.76%) 1058 (2.76%) 1058 (2.76%)
   apoptosis 9 (1.29%) 12 (1.27%) 5 (0.75%) 3 (0.69%) 373 (0.97%) 373
   (0.97%) 373 (0.97%) 373 (0.97%)
   NF-kappa B 23 (3.29%) 37 (3.91%) 11 (1.65%) 8 (1.85%) 477 (1.25%) 477
   (1.25%) 477 (1.25%) 477 (1.25%)
   Toll-like receptor signaling 22 (3.14%) 22 (2.33%) 15 (2.26%) 4 (0.93%)
   405 (1.06%) 405 (1.06%) 405 (1.06%) 405 (1.06%)
   Natural killer cell mediated cytotoxicity 36 (5.14%) 43 (4.55%) 16
   (2.41%) 8 (1.85%) 532 (1.39%) 532 (1.39%) 532 (1.39%) 532 (1.39%)
   Fc gamma R-mediated phagocytosis 33 (4.71%) 41 (4.33%) 20 (3.01%) 16
   (3.7%) 570 (1.49%) 570 (1.49%) 570 (1.49%) 570 (1.49%)
   Complement and coagulation cascades 25 (3.57%) 28 (2.96%) 20 (3.01%) 19
   (4.4%) 459 (1.2%) 459 (1.2%) 459 (1.2%) 459 (1.2%)
   B cell receptor signaling pathway 22 (3.14%) 35 (3.7%) 15 (2.26%) 11
   (2.55%) 424 (1.11%) 424 (1.11%) 424 (1.11%) 424 (1.11%)
   T cell receptor signaling pathway 15 (2.14%) 23 (2.43%) 10 (1.5%) 11
   (2.55%) 462 (1.21%) 462 (1.21%) 462 (1.21%) 462 (1.21%)
   Cytokine-cytokine receptor interaction 21 (3%) 29 (3.07%) 22 (3.31%) 5
   (1.16%) 738 (1.93%) 738 (1.93%) 738 (1.93%) 738 (1.93%)
   RIG-I-like receptor signaling pathway 8 (1.14%) 10 (1.06%) 6 (0.9%) 2
   (0.46%) 245 (0.64%) 245 (0.64%) 245 (0.64%) 245 (0.64%)
   NOD-like receptor signaling pathway 8 (1.14%) 9 (0.95%) 6 (0.9%) 2
   (0.46%) 343 (0.9%) 343 (0.9%) 343 (0.9%) 343 (0.9%)
   TGF-beta signaling pathway 2 (0.29%) 12 (1.27%) 6 (0.9%) 1 (0.23%) 344
   (0.9%) 344 (0.9%) 344 (0.9%) 344 (0.9%)
   Wnt signaling pathway 5 (0.71%) 12 (1.27%) 3 (0.45%) 3 (0.69%) 630
   (1.64%) 630 (1.64%) 630 (1.64%) 630 (1.64%)
   Ubiquitin mediated proteolysis 5 (0.71%) 11 (1.16%) 9 (1.35%) 1 (0.23%)
   668 (1.74%) 668 (1.74%) 668 (1.74%) 668 (1.74%)
   [80]Open in a new tab

   Note: 1st w, first week after infection; 2nd w, second week after
   infection; 3rd w, third week after infection; 4th w, fourth week after
   infection.

Validation of Illumina expression patterns by qRT-PCR analysis

   To confirm the reliability of the sequencing analysis and to verify the
   relationship of unigenes to resistance against S. japonicum, eight
   candidate DEGs were selected and detected by qRT-PCR. Agarose gel
   electrophoresis results showed that eight primer pairs obtained a band
   of the expected size. The profile of their expression was consistent
   with the results from the RNA-Seq (Figure [81]7) and the results
   suggested that the unigene data were highly reliable. In M. fortis,
   unigenes were up-regulated for the first three weeks after infection,
   and gradually decreased at the fourth week after infection. In mice,
   the unigenes were up-regulated after the third or the fourth week after
   infection. The time point of up-regulation for genes in BALB/c mice was
   delayed by 3–4 weeks compared to M. fortis. The expression time points
   and expression levels of unigenes in different hosts were thus
   significantly different (Figure [82]8).

Figure 7.

   Figure 7
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   Comparison of RNA-seq-derived ratios with RT-PCR analysis for selective
   genes. R^2, correlation coefficient.

Figure 8.

   Figure 8
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   Expression profiles of eight candidate DEGs in M. fortis and BALB/c
   mice. A: CD74 in BALB/c, CL2855 contig 1 in M. fortis; B, Clec4n in
   BALB/c, Unigene 29960 in M. fortis; C, Tmsb4x in BALB/c, Unigene 36673
   in M. fortis; D, Irf7 in BALB/c, Unigene 38015 in M. fortis; E, Tlr2 in
   BALB/c, Unigene 6959 in M. fortis; F, CD14 in BALB/c, Unigene 31333 in
   M. fortis; G, FcerIg in BALB/c, Unigene 36889 in M. fortis; H, Irgm1 in
   BALB/c, Cl2148 contig 4 in M. fortis. The expression value at the mRNA
   level was detected using quantitative RT-PCR. The expression times and
   expression levels of unigenes in the different hosts were significantly
   different.

Potential resistance-associated molecular analysis in M. fortis

   We further analyzed DEGs to select up-regulated or down-regulated
   unigenes in the first three weeks after infection. In this period, the
   reaction to removing schistosomula from M. fortis was the most
   dramatic. Unigenes showing changes during this period might be
   potential resistance genes. These up-regulated unigenes were grouped
   into the following categories:
     * (i)
       Metabolism-related unigenes, such as glutathione S-transferase
       kappa 1, GTPase family M protein 1, 3 beta-hydroxysteroid
       dehydrogenase, calcium-dependent phospholipase A2, mitochondrial
       precursor, apolipoprotein L, insulin-like growth factor-binding
       protein 1, serpin B9-like, cytochrome P450 4A10;
     * (ii)
       Immunity-related unigenes, such as immunoglobulin IgG heavy chain,
       h-2 class I histocompatibility antigen, CD74 antigen, MHC class II
       antigen, interferon-induced protein with tetratricopeptide repeats
       1-like, interferon regulatory factor 1, interferon regulatory
       factor 7, interferon regulatory factor 8, interferon regulatory
       factor 9, lymphocyte antigen 86-like, T cell surface glycoprotein
       CD8 alpha chain-like, B cell linker protein, monocyte
       differentiation antigen CD14-like;
     * (iii)
       Inflammation-related unigenes, such as fibronectin precursor, C-X-C
       motif chemokine 10-like, C-C motif chemokine 5, Janus kinase 3;
     * (iv)
       Apoptosis-related genes, such as caspase-8 and bcl-2 homologous
       antagonist.

   The results showed that unigenes down-regulated after infection were,
   among others, salivary gland secretion protein 4, cholesterol
   7-alpha-monooxygenase, UDP-glucuronosyltransferase 2B1-like isoform 2,
   UDP-glucuronosyltransferase 1-9-like, hematopoietically expressed
   homeobox, zinc finger and BTB domain-containing protein 16. These
   results showed that after infection of M. fortis with S. japonicum,
   metabolism, immunity, inflammation, and apoptosis-related gene
   expression levels increased, whereas synthesis was reduced.

Discussion

   M. fortis and BALB/c mice are non-permissive and permissive hosts of S.
   japonicum, respectively. After infection, the profiles of gene
   expression, immune response and pathological changes of the two hosts
   were significantly different. A previous study revealed that the lungs
   and liver of M. fortis, rats and mice display different characteristics
   when infected with S. japonicum for 10 days. M. fortis and rats, both
   of which are resistant to S. japonicum, developed a stronger immune
   response and more severe pathological lesions in response to
   schistosomes than mice during the early phase of the infection
   [[85]15]. After infection with S. japonicum, levels of cytokines,
   complements and antibodies were significantly higher in M. fortis than
   in mice [[86]9, [87]19]. In our study, the changes in cytokine
   expression were detected by using protein microarrays in the sera of M.
   fortis voles and C57BL/6 mice. Levels of Th1, Th2, and Th17 cytokines
   in M. fortis voles increased significantly during the first 3 weeks
   post-infection, while there was no significant changes in mice (Data
   not shown). It has been found that after infection with S. japonicum
   for 1 week, serine protease inhibitor gene expression was up-regulated
   and immune-associated gene expression did not change in the lung tissue
   of mice. Conversely, some important immune-associated genes (such as
   CD74, MHC-I and MHC-II) were up-regulated, and serine protease
   inhibitor gene expression did not change in M. fortis [[88]20].
   Pathological changes in the liver of M. fortis were significant during
   the first 3 weeks post-infection, while there was no significant
   changes in the liver of mice (shown in Figure [89]1). These results
   help to clarify molecular mechanisms of infection immunity in different
   hosts of S. japonicum, which might provide new ways to prevent and
   control schistosomiasis.

   To investigate the changes in gene expression and understand the
   critical genes in the response of M. fortis to S. japonicum infection,
   RNA-Seq (quantification) analysis was performed and various
   differently-expressed genes were obtained. The number of up-regulated
   genes at the second week after infection was 1,354, which was higher
   than at other time points. Compared to the second week after infection,
   the number of down-regulated genes at the third and the fourth week
   after infection was 1,202 and 1,304, respectively, which was higher
   than at other weeks. It was thus concluded that the in vivo response of
   M. fortis was the most intense at the second week after infection.
   Three weeks after infection, the response to schistosomes in M. fortis
   gradually leveled off. This result was consistent with pathological
   changes in the liver after infection. GO and pathway functional
   enrichment analysis of the DEGs showed that “cell periphery”,
   “extracellular space”, “plasma membrane”, “external side of plasma
   membrane”, “extracellular region”, “cell surface” and “cytoplasm” were
   the most significantly changed categories. These structures include
   metabolic enzymes, cell surface receptors, signaling molecules, and
   platelet-derived growth factor-binding structures. The most
   significantly and most frequently enriched terms that were up-regulated
   transcripts after infection were inflammatory, immunity-correlated
   genes, and metabolism-related enzymes (Additional file [90]8: Dataset
   S6).

   NK cells are a type of cytotoxic lymphocytes critical to the innate
   immune system. They control immune responses by secreting cytokines and
   chemokines, including tumor necrosis factor-α (TNF-α) and interferon-γ
   (IFN-γ), and eliminate target cells by polarized exocytosis of
   cytotoxic granules containing perforin, granzymes and Fas ligand
   [[91]21]. Binding of IFN-γ (or type II interferon) to its receptors
   activates the JAK-STAT pathway and has an immune-modulatory function
   [[92]22]. IFN-γ (originally called macrophage-activating factor) can
   stimulate macrophages and induce direct antimicrobial and antitumor
   mechanisms. It can also up-regulate antigen-processing and
   antigen-presenting pathways [[93]23]. IFN-γ orchestrates leukocyte
   attraction, thus enhancing NK cell activity and regulating B cell
   functions, such as immunoglobulin (Ig) production and class switching
   [[94]24]. Our results show that unigenes involved in IFN-γ, such as
   interferon regulatory factor 1, interferon regulatory factor 7,
   interferon regulatory factor 8, interferon regulatory factor 9 and
   interferon-induced protein with tetratricopeptide repeats 1-like, were
   significantly up-regulated. Simultaneously, by using genome
   oligonucleotide microarrays, some studies also reported that after
   infection with S. japonicum for 10 days, a gene similar to IFN-γ
   receptor 2 was up-regulated in the lungs of M. fortis [[95]15]. Members
   of the TNF/TNF-receptor (TNF-R) superfamily coordinate the immune
   response at multiple levels, such as by lymphoid neogenesis, augmenting
   immune responses and apoptosis dependent on caspase 8. Among these,
   acute TNF-R engagement can induce the rapid and robust activation of
   NF-κB and MAPK pathways [[96]25]. In our study, the TNF-related genes
   and pathways were significantly up-regulated. These included
   TNF-receptor binding (ligand) superfamily, TNF-mediated signaling
   pathway, TNF-activated receptor activity member 1B precursor, TNF
   binding, caspase 8 (K04398), apoptosis, NF-κB and MAPK pathways. This
   indicates that IFN-γ and TNF might play important roles in the response
   against S. japonicum infections.

   TLRs are among the best-characterized PRRs and are key regulators of
   anti-pathogen immune responses. Schistosomal-derived
   lysophosphatidylcholine participates in the production of cytokines,
   such as TNF-α and IL-10, and in eosinophil activation through a
   TLR2-dependent pathway in S. mansoni and S. haematobium infection
   [[97]26, [98]27]. Antigen-presenting cells (APCs) recognize
   lysophosphatidylserine and schistosomal glycolipids of schistosomes
   through TLRs, leading to NF-κB and MAPK signaling pathway activation
   and inducing inflammatory cytokine production [[99]28].

   The CD14 antigen is a glycosylphosphatidylinositol (GPI)-anchored
   receptor known to serve as a co-receptor for several TLRs that were
   significantly up-regulated in M. fortis after infection with S.
   japonicum. Earlier studies showed a role for CD14 as a co-receptor
   working with TLR4 and facilitating cellular responses to low doses of
   lipopolysaccharide (LPS). Upon LPS stimulation, CD14 enables the
   activation of the TLR4-TRAM-TRIF pathway and leads to the activation of
   NFAT transcription factor family members [[100]29]. This suggests that
   CD14 and TLRs play an important role in initiating inflammation by
   responding to LPS stimulation in M. fortis.

   Adaptive immunity is an important part of the anti-schistosomiasis
   mechanism in M. fortis. Three weeks after infection, many unigenes were
   involved in adaptive immunity, including immunoglobulin IgG heavy
   chain, Fc receptor of IgE and CD8A antigen protein complex, CD74.
   Antibodies are major components of the immune system. IgG is the main
   antibody isotype found in blood and extracellular fluid, allowing it to
   control the infection of body tissues. IgG can mediate a variety of
   biological functions, such as the classical pathway of complement
   activation, ADCC, hypersensitivity, and can block pathogens. The Fc
   receptors of IgE are proteins called Fc-epsilon receptors (FcϵR) found
   on the surface of certain cells - including mast cells, eosinophils,
   basophils and Langerhans cells - that contribute to the protective
   functions of the immune system [[101]30]. The CD8 antigen is a cell
   surface glycoprotein found on most cytotoxic T lymphocytes that
   mediates efficient cell-cell interactions within the immune system.
   CD74, known as the major histocompatibility complex (MHC) class II
   invariant chain, regulates the trafficking of MHC-II in APCs and acts
   as a receptor for macrophage migration inhibitory factor (MIF). After
   the binding of the MIF, NF-κB and Erk1/2 activation occurs, along with
   the induction of proinflammatory cytokine secretion [[102]31]. It has
   been reported that the serum of M. fortis was passively transferred in
   mice, which not only reduced worm burden but also led to worm
   shortening [[103]32]. Another report showed that purified IgG3
   antibodies from laboratory-bred M. fortis and wild M. fortis
   effectively killed schistosomula, and that IgG3 antibodies of wild M.
   fortis induced a higher worm-reduction rate. The death rates of
   schistosomula due to IgG3 antibody purified from the sera of
   laboratory-bred M. fortis and wild M. fortis were 2.35 and 5.88 times
   higher than in Km mice, respectively [[104]33]. It has been shown that
   the sera and/or spleen cells of M. fortis had an important effect on
   killing schistosomula in vitro. This study could also show a synergism
   between sera of M. fortis and spleen cells [[105]34]. In our study,
   after infection with S. japonicum for three weeks, cytokines (such as
   IL-4, IL-5, IL-6, IL-13, TNF-α and GM-CSF) in the sera of M. fortis
   were significantly increased, whereas cytokine levels of the BALB/c
   mice were much lower (data not shown). These findings suggest that
   these parasite-killing effects were performed in part by CD8^+ T and B
   lymphocytes.

Conclusions

   In summary, we first characterized the M. fortis de novo transcriptome
   and performed RNA-Seq quantification analysis after infection with S.
   japonicum. A total of 134,985,444 clean reads, 166,501 contigs and
   67,751 unigenes were obtained. Based on the assembled de novo
   transcriptome, the amount of DEGs that play significant roles in the
   response to schistosome infection were identified. The numbers of DEGs
   at weeks 1–4 were 1741, 2178, 1683 and 1197, respectively. We concluded
   that the in vivo response of M. fortis was the most intense at the
   second week after infection. GO and pathway enrichment analysis
   revealed that after infection the up-regulated DEGs were predominately
   involved in metabolism, inflammation response and immunity response.
   The natural and adaptive immune responses, particularly NK cell
   activation producing IFN-γ and TGF-β, TLR activation of macrophages,
   and IgG and IgE antibodies produced by B lymphocytes, play an important
   role in M. fortis resistance against S. japonicum. Multiple candidate
   genes involved in innate immune responses were identified further with
   qRT-PCR, and expression patterns in M. fortis and BALB/c mice were
   compared. The results reflected significant differences of innate
   immune responses and different sensitivities in the hosts of
   schistosomes. This study provides a valuable molecular basis for the
   analysis of M. fortis resistance mechanisms against S. japonicum.

Methods

Ethics statement

   This study was performed in strict accordance with the recommendations
   of the Laboratory of Animal Welfare & Ethics Committee (LAWEC) of
   China. No specific permissions from Hunan provincial authorities were
   required because the study did not involve endangered or protected
   species. The protocol was approved by the LAWEC Committee of the
   National Institute of Parasitic Diseases, Chinese Center for Disease
   Control and Prevention (approval ID: IPD 2009–4). All surgery was
   performed under sodium pentobarbital anesthesia, and all efforts were
   made to minimize suffering.

Animals and cercariae

   M. fortis voles were live captured in the Hunan Dongtin Lakes region,
   China. The animals were transported to Shanghai and reared in
   independent ventilated cages. Fifteen M. fortis females (aged 7–8
   weeks, weighing 60–70 g) were randomly selected from a sub-generation
   of wild animals to be used in the experiment. BALB/c mice (aged 7–8
   weeks, weighing 20–25 g) were purchased from the Experimental Animal
   Department of the Chinese Academy of Sciences. The animals were
   infected cutaneously (see below) with a mainland strain of S. japonicum
   cercariae. Infected Oncomelanias hupensis snails were provided by the
   National Institute of Parasitic Diseases, Chinese Center for Disease
   Control and Prevention. The infected snails were placed in
   dechlorinated water under artificial light to induce cercarial shedding
   before animal infections.

Sample preparation

   M. fortis voles and BALB/c mice were infected percutaneously with S.
   japonicum cercariae. Based on the susceptibility of each rodent species
   to S. japonicum, M. fortis voles were infected with 1,000 cercariae and
   BALB/c mice were infected with 40 cercariae per individual. Fifteen M.
   fortis voles and 15 BALB/c mice were divided into five groups randomly.
   Animals in each group were sacrificed either before infection or at 1,
   2, 3 and 4 weeks post-infection. Before the animals were sacrificed,
   they were anesthetized with 0.75% sodium pentobarbital by
   intraperitoneal injection, and the livers of the animals were removed,
   frozen in liquid nitrogen and stored at -80°C until further use.

Preparation of cDNA library and Illumina sequencing for transcriptome
analysis

   Total RNA was extracted using Trizol reagent (Invitrogen, USA)
   following the manufacturer’s protocol. After total RNA extraction and
   DNase I treatment, magnetic beads with Oligo (dT) were used to isolate
   mRNA. The mRNA was fragmented into short fragments when it was mixed
   with the fragmentation buffer. Then, cDNA was synthesized using the
   mRNA fragments as templates. The short fragments were purified and
   resolved with EB buffer for end reparation and single nucleotide A
   (adenine) addition. Afterwards, the short fragments were connected with
   adapters. The suitable fragments were selected as templates for PCR
   amplification. During the QC steps, an Agilent 2100 Bioanalyzer and an
   ABI StepOnePlus Real-Time PCR System were used for quantification and
   qualification of the sample library. The library was sequenced using
   Illumina HiSeq™ 2000.

   Raw reads were produced from the sequences. Clean reads were obtained
   after removal of low quality reads, reads with adaptors and reads with
   unknown nucleotides larger than 5%. A de novo transcriptome assembly
   was performed using the short reads assembling program Trinity
   [[106]35]. The resulting sequences obtained from Trinity are called
   unigenes. Then, a BLASTx alignment (E-value < 0.00001) between unigenes
   and protein databases, such as NR, Swiss-Prot, KEGG and COG, was
   performed, and the best alignment results were used to determine the
   sequence direction of the unigenes. With NR annotation, we used the
   Blast2GO program [[107]36] to obtain the GO annotation of the unigenes.
   After obtaining the GO annotation for every unigene, we used WEGO
   software [[108]37] to perform a GO functional classification for all
   unigenes and to further understand the distribution of gene functions
   in the species on a macroscopic level. We predicted genes with
   different expression levels, and performed GO functional analysis and
   KEGG pathway analysis on them.

RNA-Seq quantification analysis

   Four independent cDNA libraries were constructed for the four liver
   samples according to the RNA-Seq protocol. Raw image files were
   collected using the Illumina HiSeqTM2000 sequencing platform in BGI
   Shenzhen, China ([109]http://en.genomics.cn/navigation/index.action).
   The analyzed data have been deposited in the NCBI Sequence Read Archive
   under the Accession No. SRX337491.

Screening of DEGs

   Screening of DEGs included the screening of genes that are
   differentially expressed among samples followed by a GO functional
   enrichment analysis and a KEGG pathway enrichment analysis for these
   DEGs. The expression level of each gene was measured via RNA-Seq
   quantification analysis using the RPKM [[110]38] method (reads per kb
   per million reads). Referring to “The significance of digital gene
   expression profiles” [[111]39], we developed a strict algorithm (the
   Poisson distribution) to identify DEGs between two samples. We
   performed a cluster analysis of gene expression patterns with cluster
   [[112]40] software and Java Treeview [[113]41] software.

   GO offers a dynamically-updated controlled vocabulary and a strictly
   defined concept to comprehensively describe properties of genes and
   their products in any organism. GO enrichment analysis provides all GO
   terms that are significantly enriched in DEGs compared to the genome
   background and filters those DEGs that correspond to biological
   functions. This method first maps all DEGs to GO terms in a database
   ([114]http://www.geneontology.org/). Genes usually interact with one
   another to play roles in certain biological functions. The pathway
   enrichment analysis identified significantly enriched metabolic
   pathways or signal transduction pathways in DEGs compared with the
   entire genome background.

RNA isolation for reverse transcription and real-time quantitative PCR (qPCR)

   Total RNA was extracted from the livers of M. fortis and BALB/c mice
   using a QIAgen RNeasy Mini Kit according to the manufacturer’s
   specifications. The RNA was determined using a NanoDrop 2000
   spectrophotometer (Thermo Scientific, USA), and the integrity was
   evaluated using electrophoresis on an agarose gel stained with ethidium
   bromide. Reactions were performed in a GeneAmp® PCR System 9700
   (Applied Biosystems, USA) for 15 min at 37°C, followed by heat
   inactivation of RT for 5 s at 85°C. Real-time PCR was performed using a
   LightCycler® 480 II Real-time PCR Instrument (Roche, Switzerland) with
   10 μl of PCR reaction mixture. Reactions were incubated in a 384-well
   optical plate (Roche, Switzerland) at 95°C for 10 min, followed by
   40 cycles of 95°C for 10 s and 60°C for 30 s. Each sample was analyzed
   in triplicates. At the end of the PCR cycles, a melting curve analysis
   was performed to validate the specific generation of the expected PCR
   product. The primer sequences (Additional file [115]9: Table S3) were
   designed in the laboratory and synthesized by Generay Biotech (Generay,
   China) based on the mRNA sequences obtained from the NCBI database and
   the RNA-Seq. The expression levels of mRNAs were normalized to GAPDH
   and were calculated using the 2^-ΔΔCt method [[116]42].

Availability of supporting data

   Raw sequence read data were submitted to the NCBI Sequence Read Archive
   under the Accession No. SRX337491,
   [117]http://www.ncbi.nlm.nih.gov/bioproject/PRJNA215691).

Electronic supplementary material

   [118]12864_2013_6159_MOESM1_ESM.doc^ (24KB, doc)

   Additional file 1: Table S1: Statistics of assembly quality. (DOC 24
   KB)
   [119]12864_2013_6159_MOESM2_ESM.doc^ (23.5KB, doc)

   Additional file 2: Table S2: Summary of annotation results. (DOC 24 KB)
   [120]12864_2013_6159_MOESM3_ESM.zip^ (163.3KB, zip)

   Additional file 3: Dataset S1: Pathways of M. fortis liver-unigenes.
   (ZIP 163 KB)
   [121]12864_2013_6159_MOESM4_ESM.zip^ (44.3KB, zip)

   Additional file 4: Dataset S2: GO terms for MfA-VS-MfA1W_C. (ZIP 44 KB)
   [122]12864_2013_6159_MOESM5_ESM.zip^ (64.1KB, zip)

   Additional file 5: Dataset S3: GO terms for MfA-VS-MfA2W_C. (ZIP 64 KB)
   [123]12864_2013_6159_MOESM6_ESM.zip^ (41.9KB, zip)

   Additional file 6: Dataset S4: GO terms for MfA-VS-MfA3W_C. (ZIP 42 KB)
   [124]12864_2013_6159_MOESM7_ESM.zip^ (25.8KB, zip)

   Additional file 7: Dataset S5: GO terms for MfA-VS-MfA4W_C. (ZIP 26 KB)
   [125]12864_2013_6159_MOESM8_ESM.xls^ (20KB, xls)

   Additional file 8: Dataset S6: Trends of consistent genes for three
   weeks after infection. (XLS 20 KB)
   [126]12864_2013_6159_MOESM9_ESM.xls^ (570.5KB, xls)

   Additional file 9: Table S3: Primer sequences used in qPCR. (XLS 570
   KB)

Acknowledgments