Figures
Abstract
The interferon-induced proteins with tetratricopeptide repeats (IFITs) protein family mediates antiviral effects by inhibiting translation initiation, cell proliferation, and migration in the interferon (IFN) dependent innate immune system. Several members of this family, including IFIT1, IFIT2, IFIT3 and IFIT5, have been heavily studied in mammals. Avian species contain only one family member, IFIT5, and little is known about the role of this protein in birds. In this study, duck IFIT5 (duIFIT5) full-length mRNA was cloned by reverse transcription polymerase chain reaction (RT-PCR) and rapid amplification of the cDNA ends (RACE). Based on the sequence obtained, we performed a series of bioinformatics analyses, and found that duIFIT5 was most similar to homologs in other avian species. Also, duIFIT5 contained eight conserved TPR motifs and two conserved multi-domains (TPR_11 and TPR_12). Finally, we used duck hepatitis virus type 1 (DHV-1) and polyriboinosinicpolyribocytidylic acid (poly (I:C)) as a pathogen or a pathogen-associated molecular pattern induction to infect three-day-old domestic ducklings. The liver and spleen were collected to detect the change in duIFIT5 transcript level upon infection by quantitative real-time PCR (qRT-PCR). DuIFIT5 expression rapidly increased after DHV-1 infection and maintained a high level, while the transcripts of duIFIT5 peaked at 8h after poly (I:C) infection and then returned to normal. Taken together, these results provide a greater understanding of avian IFIT5.
Citation: Wang B, Chen Y, Mu C, Su Y, Liu R, Huang Z, et al. (2015) Identification and Expression Analysis of the Interferon-Induced Protein with Tetratricopeptide Repeats 5 (IFIT5) Gene in Duck (Anas platyrhynchos domesticus). PLoS ONE 10(3): e0121065. https://doi.org/10.1371/journal.pone.0121065
Academic Editor: Michelle L. Baker, CSIRO, AUSTRALIA
Received: October 14, 2014; Accepted: January 27, 2015; Published: March 27, 2015
Copyright: © 2015 Wang et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited
Data Availability: All relevant data are within the paper and its Supporting Information files.
Funding: The study was supported by the National Waterfowl Industrial Technology System (No. CARS-43-3), the Excellent PhD Dissertation Foundation of Yangzhou University and the Project Funded by the Priority Academic Program Development of Jiangsu Higher Education Institutions ([2011]137). The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.
Competing interests: The authors have declared that no competing interests exist.
Introduction
The innate immune system relies on a class of cytokines known as interferons (IFNs), which are secreted by host cells in response to viral infection [1,2]. IFNs, combined with specific cell surface receptors, lead to high expression of a large group of IFN-stimulated genes (ISGs), which inhibit viral replication, transcription and cell proliferation [3,4].
IFITs are among the most predominant ISGs, and based on extensive studies from recent years, have been shown to play a significant role during viral infection [5]. Four members, IFIT1 (p56; ISG56), IFIT2 (p54; ISG54), IFIT3 (p60; ISG60), and IFIT5 (p58; ISG58), constitute an intimate family in mammals. IFITs are conserved in mammals, amphibians and fish, but do not exist in lower animals. IFIT5 is the sole family member found in birds. Very little is known about the function of IFIT5 in birds.
IFITs are characterized by multiple tetratricopeptide repeats (TPRs), degenerate helix–turn–helix motifs of 34 amino acids in length. Different IFIT family members have distinct numbers of TPR motifs, for example, IFIT1 has six TPR motifs, while IFIT5 has eight. Over the past decade, the antiviral activity and mechanisms of action of IFIT proteins have been gradually elucidated. Recently, IFIT family members have been shown to selectively restrict viral replication by sensing the methylation status of the 5’-cap of some viral RNAs [6–8]. Viruses hijack a cap from host mRNA or encode machinery to add a 5’-cap structure to their mRNA, thereby escaping IFIT recognition [9]. More recently, the structural basis for viral 5’-PPP-RNA recognition by human IFIT proteins has been unraveled, which validated the mechanism by which IFIT proteins selectively recognize viral single-stranded RNA (ssRNA) [10].
In this study, we presented the molecular cloning and characterization of duIFIT5 and analyzed its expression during duck hepatitis virus type 1 (DHV-1) and poly (I:C) infection, to investigate infection by a single-stranded RNA (ssRNA) and a double-stranded RNA (dsRNA), respectively. These data facilitated a better understanding of the role of duIFIT5 in immunity, thus providing tools for future immunopathological studies.
Materials and Methods
Ethics Statement
All animal experiments were reviewed and approved by the Institutional Animal Care and Use Committee of Yangzhou University. Experiments were performed in accordance with the Regulations for the Administration of Affairs Concerning Experimental Animals (Yangzhou University, China, 2012) and the Standards for the Administration of Experimental Practices (Jiangsu, China, 2008). All operations were performed according to recommendations proposed by the European Commission (1997), and all efforts were made to minimize suffering.
Animals and sample collection
All animals were obtained from the Chinese Waterfowl Germplasm Resource Pool (Taizhou, China). To characterize gene expression, various tissues, including heart, liver, spleen, lung, kidney, large intestine, small intestine, muscle, cerebrum, cerebellum, glandular stomach and muscular stomach, were collected from healthy, adult, domestic ducks, frozen in liquid nitrogen, and stored at −80°C.
120 three-day-old domestic ducklings were randomly assigned to three groups and injected with 0.4 mL of either allantoic fluid containing DHV-1, poly (I:C) (0.5 mg/mL, Invitrogen, USA), or saline (as a control). Ducklings inoculated with DHV-1 appeared depressed soon, showed little desire to eat, and began to die 1.5 d.p.i, whereas the forty ducklings inoculated with poly (I:C) and saline have no symptoms. Samples from ducklings with no symptoms were collected at 0, 4, 8, 12, 24, 36, 48, 72, and 96 h after injection. 4 ducklings per group were euthanized after anesthesia with intraperitoneal injection of sodium pentobarbital (150mg/kg) at each time point. The spleen and liver were snap-frozen in liquid nitrogen immediately after dissection and stored at -80°C. Ducklings displayed symptoms were anaesthetic by using a low dose of sodium pentobarbital (50mg/kg). If ducklings displayed serious symptoms and seemed moribund, they would be euthanized by using a high dose of sodium pentobarbital (150mg/kg) and decollation.
RNA extraction and cDNA synthesis
Total RNA was extracted using Trizol reagent (Takara) according to the standard protocol. 1 μg of RNA isolated from the tissues was used to synthesize first strand cDNA with the cDNA synthesis kit (Takara) according to the manufacturer’s protocol.
Cloning of duIFIT5
The TaKaRa 5’-Full RACE Kit and 3’-Full RACE Core Set Ver.2.0 were used according to the manufacturer’s instructions to amplify the 5’ and 3’ ends of the cDNA, respectively. RACE primers (S1 Table) were designed using the duIFIT5 CDS obtained from RT-PCR. Touchdown and nested PCRs were performed according to the manufacturer’s instructions. Amplication were then cloned into a plasmid vector for nucleotide sequencing, as described above.
Bioinformatic analysis
BLASTn (http://blast.ncbi.nlm.nih.gov/Blast.cgi) was used to identify genes with homology to IFIT5. Homology analyses of nucleotide and amino acid sequences were performed with DNAstar software. A phylogenetic tree was generated by the neighbor joining method with 1000 bootstrap replicates in MEGA5.0. ESPript3.0 (http://espript.ibcp.fr/ESPript/cgi-bin/ESPript.cgi) was used to construct multiple alignments of the amino acid sequences of IFIT5 proteins. Conserved domains within duIFIT5 and human IFIT5 were identified through NCBI (http://www.ncbi.nlm.nih.gov/Structure/cdd/wrpsb.cgi). The primary structure and subcellular localization was analyzed using the ExPASy ProtParam tool (http://espript.ibcp.fr/ESPript/cgi-bin/ESPript.cgi) and PSORT II Protein Sorting Prediction program (http://psort.ims.u-tokyo.ac.jp/form2.html).
Quantitative real-time PCR (qRT-PCR)
To quantify duIFIT5 gene expression patterns, cDNA from different tissues was amplified in a 20 μL reaction using the Applied Biosystems 7500 real-time PCR system with the following program: 1 cycle at 95°C for 30 s, followed by 40 cycles of 95°C for 5 s and 60°C for 34 s. All cDNA samples were tested three times, and the results were normalized to duck glyceraldehyde-3-phosphate dehydrogenase (GAPDH) expression. The primers designed for real-time PCR (P7 and P8 for duIFIT5; P9 and P10 for GAPDH) are shown in S1 Table. The relative expression levels of duIFIT5 in healthy and infected ducks were indicated by the 2− ΔCt and 2− ΔΔCt methods, respectively.
Construction of plasmids and transient transfection
The CDS of duIFIT5 (P1 and P2) was cloned into the EGFP-C1 vector (Invitrogen, USA) digested with XbaI and KpnI to produce the EGFP-C1-duIFIT5 plasmid. DF1 cells were seeded at 2×105 cells/well (24-well plate), grown to 80% confluence, and then transfected with 2 μL Lipofectamine-2000 transfection reagent (Invitrogen, USA) and 1μg of plasmid DNA (EGFP-C1-duIFIT5 or EGFP-C1) according to the manufacturer’s instructions. The complexes were removed after 6 h, and the complete growth medium was replaced. Finally, fluorescence microscopy was used to detect the fluorescence in each well at 24 h post-transfection.
Results
cDNA cloning of duIFIT5 and bioinformatics analysis
The full-length cDNA sequence of duIFIT5 was 2146 bp in size, including a 71 bp 5′ UTR and a 635 bp 3′ UTR with the poly [A] tail (Genbank accession No.KF956064). The open reading frame (ORF) was 1440 bp in length and encoded a predicted protein of 479 amino acids. The nucleotide and predicted amino acid sequences of the duIFIT5 gene are shown are shown in S1 Fig.
DNAStar software was used to analyze duIFIT5. Compared to the homologous gene sequences of nine other species obtained from Genbank, it had the highest homology to Falco cherrug (up to 80.1%), followed by Meleagris gallopavo (up to79.7%), and about 50% homology with other species (S2 Fig.). A condensed phylogenetic tree was constructed based on the amino acid sequence of duIFIT5 compared to homologs in other organisms (Fig. 1). The overall topology of the tree revealed three major groups, including mammals, birds, and fish. DuIFIT5 was most similar to homologs of the other avian species. Aligning the amino acid sequences of duIFIT5 homologs from several species using ESPript3.0 software, we found that the amino acid sequences were conserved between mammals, fish, and birds (S3 Fig.). The conserved domains predicted from the amino acid sequence included eight TPR modifs and two multi-domains (TPR_11 and TPR_12), which is similar to the domain structure of human IFIT5 (Fig. 2). The ExPASyProtParam and PSORT Protein Sorting Prediction tools were used to analyze the primary structure and subcellular localization of duIFIT5. Primary structure analysis showed that the predicted molecular weight was 55780.8 Da with a theoretical isoelectric point of 6.57. Subcellular localization analysis predicted that duIFIT5 would be highly expressed in both the cytoplasm and nucleus (S2 Table).
Numbers at each branch indicate the percent a node was supported in 1,000 bootstrap replicates.
Both duIFIT5and human IFIT5 have eight TPR motifs and multi-domains TPR_11 and TPR_12.
Subcellular localization of duIFIT5 in DF1 cells
To confirm the above prediction, the EGFP-C1-duIFIT5 plasmid, or EGFP-C1 as a negative control, was transfected into chicken embryo fibroblasts (DF1 cells), and fluorescence was observed 24 h post-transfection (Fig. 3). DuIFIT5 was predominantly in the cytoplasmic, but was also visualized in the nucleus.
EGFP-C1-duIFIT5 or an EGFP-C1 control plasmid was transiently transfected into DF1 cells, shown in A and B, respectively. DuIFIT5 was mostly in the cytoplasmic, but was also detected in the nucleus.
Tissue expression of duIFIT5 in healthy ducks
To determine which tissues expressed duIFIT5, qRT-PCR was performed using gene specific primers and cDNA templates synthesized from several tissues taken from healthy ducks. DuIFIT5 mRNA was constitutively expressed in all 12 tissues tested. The highest expression levels were observed in intestine (large intestine and small intestine) and stomach (glandular stomach and muscular stomach) tissues, whereas the expression levels in other tissues were relatively low, especially in heart, kidney and muscle. (Fig. 4).
The expression of duIFIT5 was normalized to GAPDH. Different letter showed significant difference (p < 0.05).
Temporal expression of duIFIT5 after DHV-1 and poly (I:C) injection
Upon infection of ducklings with DHV-1, the major pathological change is hepatitis. The same situation also appeared in the dead ducklings of our experiment. In addition, the spleen is an important organ for immune system function. Therefore, liver and spleen tissues of treated and untreated groups were collected to study the temporal expression of duIFIT5 with injection of foreign RNA. The mRNA expression levels of duIFIT5 in liver and spleen were measured at various time points after injection (0, 4, 8, 12, 24, 36, 48, 72, 96 h) by qRT-PCR. For animals infected with DHV-1, some subtle differences were observed in the expression patterns of the spleen compared to the liver. In the liver, duIFIT5 expression sharply increased more than 200- fold from 0–48 hours post-infection and expression levels remained high compared with that of the control for the duration of the experiment. In the spleen, duIFIT5 expression peaked at 36 h post-infection, but only demonstrated a 40-fold increase with that of the control (Fig. 5). After poly (I:C) injection, duIFIT5 expression rapidly increased in both liver and spleen during the first eight hours post infection and reached a peak of 10–20 fold with that of that control, then returned to normal levels by 36 h post induction (Fig. 6). These results showed that duIFIT5 sharply increased following both types of viral infection, but the temporal expression patterns of DHV-1 group and poly (I:C) group were different. The expression pattern of DHV-1group was similar between the liver and spleen, but duIFIT5 shown a stronger increase in liver.
qRT-PCR was used to determine the relative expression of duIFIT5 in liver and spleen tissues at 0, 4, 8, 12, 24, 36, 48, 72 and 96 h after infection with DHV-1. The expression of duIFIT5 was normalized to GAPDH. Different letter showed significant difference (p < 0.05).
qRT-PCR was used to determine the relative expression of duIFIT5 in liver and spleen tissues at 0, 4, 8, 12, 24, 36, 48, 72 and 96 h after infection with poly (I:C). The expression of duIFIT5 was normalized to GAPDH. Different letter showed significant difference (p < 0.05).
Discussion
We cloned the 2146-bp mRNA of duIFIT5, performed bioinformatics analysis, and determined the subcellular localization of duIFIT5 in DF1 cells. We found duIFIT5 was closely related to homologs found in turkey and chicken. Aligning the amino acid sequences of duIFIT5 homologs from several species, we found that the domains were conserved between mammals, fish, and birds. The analyses provided an evidence that the IFIT family is evolutionarily conserved from mammals to birds. Besides, the conserved domains of duIFIT5 consisted of eight TPR motifs and two multi-domains (TPR_11 and TPR_12), which was similar to the domain structure of human IFIT5. The presence of tandem arrays of multiple TPR domains provides a well-suited space for mediating protein–protein interactions, potentially allowing IFIT proteins to bind to specific proteins and RNAs, regulating the cell cycle[11–13]. Recently, the crystal structure of IFIT protein has been elucidated, revealing that helix-turn-helix TPR-like structures exist in each subunit, forming a nucleotide channel which binds specific proteins and RNAs[14,15]. This prompted us duIFIT5 may have a similar fuction as human IFIT5.
Although IFITs are normally quiescent, their transcription is strongly induced by IFNs, virus infection, and molecular patterns such as double-stranded RNA or lipopolysaccharides [16,17]. We have demonstrated that this is coincident for duIFIT5. The relative expression level of duIFIT5 compared to GAPDH is very low in most tissues, except in the intestine and the stomach. The high expression in these tissues may be attributed to unknown microbes in these organs, such as viruses, bacteria, and fungi, which potentially trigger induction of IFNs [18,19].
Following we decided to mimic foreign RNA viral infection in vivo to determine the temporal expression of duIFIT5 after DHV-1 and poly (I:C) infection. The challenging ducklings experiment with DHV-1 and poly (I:C) infection resulted in two different duIFIT5 temporal expression patterns. There was a strong increase in duIFIT5 expression during both types of viral infection, however, the experiment revealed a different expression tendency to DHV-1and poly (I:C). In DHV-1 group, duIFIT5 expression sharply increased to a peak and maintained high. In Poly (I:C) group, duIFIT5 expression increased to a peak and rapidly returned to the normal. This phenomenon may be caused by ducklings’ different resistance to the two viruses. DHV-1 is an acute and fatal disease of young ducklings. It is very prevalent and results in mortality rates higher than 90% in infected ducklings under 3 weeks of age [20–22]. As IFN-αtranscripts greatly increase following DHV-1 infection[23], the elevated expression of duIFIT5 was expected in our study. And the recent hypothesis that IFIT5 specifically engage single-stranded 5’-PPP-RNA could also explain why abundant transcripts of duIFIT5 persisted in both liver and spleen. The major pathologic change in infected ducklings is hepatitis, hence, the exceptionally higher expression level detected in the liver may be due to higher pressure against numerous viruses. Similar IFIT5 expression changes have been observed upon avian influenza infection. Several papers have shown that IFIT5 is very highly expressed in avian influenza infected ducklings [24,25]. Poly (I:C) is a synthetic double-stranded RNA that has been identified as a product of viral replication [26]. Previous studies have demonstrated that IFN-β and ISGs were over expressed by host cells after poly (I:C) infection [27]. Our result indicates that upon poly (I:C) infection duIFIT5 obviously increased. Poly (I:C) is nontoxic or lentogenic to duck, so the rapid return to basal level of duIFIT5 expression might be because ducklings have a relatively high resistance to poly (I:C). Besides, our previous study have shown that duck RIG-I gene had a similar expression pattern after poly (I:C) infection[28]. RIG-I is considered to be a upstream gene for IFITs[29,30], so the result could also demonstrate that duck RIG-I and IFIT5 are well connected. Together, our study revealed duIFIT5 take part in both ssRNA and dsRNA innate immune process, and two different expression patterns of duIFIT5 are put forth. These results provide a better understanding of IFIT5 in avian species.
Supporting Information
S1 Fig. Nucleotide and predicted amino acid sequences of duIFIT5.
https://doi.org/10.1371/journal.pone.0121065.s001
(TIF)
S2 Fig. Homology comparison of IFIT5 amino acid sequences in duck and other vertebrates.
The columns and rows show numbers representing each species. The intersection between a row and column shows the amino acid homology of IFIT5 for the two corresponding species.
https://doi.org/10.1371/journal.pone.0121065.s002
(TIF)
S3 Fig. Amino acid alignment of IFIT5 homologs.
The alignment of primary and secondary structure of IFIT5 proteins from ten species, Homo sapiens (Homo), Gallus gallus (Gallus), Meleagris gallopavo (Meleagris), Anas platyrhynchosv (Anas), Sus scrofa (Sus), Bos Taurus (Bos), Poephila guttata (Poephila), Macaca fascicularis (Macaca), Equus caballus (Equus), Oreochromis niloticus (Oreochromis) was shown. Ten species of IFIT5 proteins have similar amino acid sequences.
https://doi.org/10.1371/journal.pone.0121065.s003
(TIF)
S2 Table. Prediction of duIFIT5 subcellular localization.
https://doi.org/10.1371/journal.pone.0121065.s005
(DOCX)
Author Contributions
Conceived and designed the experiments: GHC BW YC. Performed the experiments: YHS RL ZYH YL. Analyzed the data: GBC QX CYM GHC. Contributed reagents/materials/analysis tools: QMY BW GHC. Wrote the paper: BW YC.
References
- 1. Koyama S, Ishii KJ, Coban C, Akira S. Innate immune response to viral infection. Cytokine. 2008;43(3):336–41. pmid:18694646
- 2. Takeuchi O, Akira S. Innate immunity to virus infection. Immunological reviews. 2009;227(1):75–86. pmid:19120477
- 3. Fensterl V, Sen GC. Interferons and viral infections. Biofactors. 2009;35(1):14–20. pmid:19319841
- 4. De Veer MJ, Holko M, Frevel M, Walker E, Der S, Paranjape JM, et al. Functional classification of interferon-stimulated genes identified using microarrays. Journal of leukocyte biology. 2001;69(6):912–20. pmid:11404376
- 5. Zhou X, Michal JJ, Zhang L, Ding B, Lunney JK, Liu B, et al. Interferon induced IFIT family genes in host antiviral defense. International journal of biological sciences. 2013;9(2):200–8. pmid:23459883
- 6. Szretter KJ, Daniels BP, Cho H, Gainey MD, Yokoyama WM, Gale M Jr, et al. 2′-O methylation of the viral mRNA cap by West Nile virus evades ifit1-dependent and-independent mechanisms of host restriction in vivo. PLoS pathogens. 2012;8(5):e1002698. pmid:22589727
- 7. Daffis S, Szretter KJ, Schriewer J, Li J, Youn S, Errett J, et al. 2'-O methylation of the viral mRNA cap evades host restriction by IFIT family members. Nature. 2010;468(7322):452–6. pmid:21085181
- 8. Zust R, Cervantes-Barragan L, Habjan M, Maier R, Neuman BW, Ziebuhr J, et al. Ribose 2'-O-methylation provides a molecular signature for the distinction of self and non-self mRNA dependent on the RNA sensor Mda5. Nature immunology. 2011;12(2):137–43. pmid:21217758
- 9. Decroly E, Ferron F, Lescar J, Canard B. Conventional and unconventional mechanisms for capping viral mRNA. Nature Reviews Microbiology. 2012;10(1):51–65. pmid:22138959
- 10. Abbas YM, Pichlmair A, Gorna MW, Superti-Furga G, Nagar B. Structural basis for viral 5'-PPP-RNA recognition by human IFIT proteins. Nature. 2013;494(7435):60–4. pmid:23334420
- 11. D'Andrea LD, Regan L. TPR proteins: the versatile helix. Trends in biochemical sciences. 2003;28(12):655–62. pmid:14659697
- 12. Diamond MS, Farzan M. The broad-spectrum antiviral functions of IFIT and IFITM proteins. Nature reviews Immunology. 2013;13(1):46–57. pmid:23237964
- 13.
Ullah MO, Ve T Fau—Mangan M, Mangan M Fau—Alaidarous M, Alaidarous M Fau—Sweet MJ, Sweet Mj Fau—Mansell A, Mansell A Fau—Kobe B, et al. The TLR signalling adaptor TRIF/TICAM-1 has an N-terminal helical domain with structural similarity to IFIT proteins. (1399–0047 (Electronic)).
- 14. Sen GC, Fensterl V. Crystal structure of IFIT2 (ISG54) predicts functional properties of IFITs. Cell research. 2012;22(10):1407–9. pmid:22964712
- 15. Feng F, Yuan L, Wang YE, Crowley C, Lv Z, Li J, et al. Crystal structure and nucleotide selectivity of human IFIT5/ISG58. Cell research. 2013;23(8):1055–8. pmid:23774268
- 16. Fensterl V, Sen GC. The ISG56/IFIT1 gene family. Journal of interferon & cytokine research: the official journal of the International Society for Interferon and Cytokine Research. 2011;31(1):71–8.
- 17. Berchtold S, Manncke B, Klenk J, Geisel J, Autenrieth IB, Bohn E. Forced IFIT-2 expression represses LPS induced TNF-alpha expression at posttranscriptional levels. BMC immunology. 2008;9(1):75.
- 18. de Weerd NA, Samarajiwa SA, Hertzog PJ. Type I interferon receptors: biochemistry and biological functions. The Journal of biological chemistry. 2007;282(28):20053–7. pmid:17502368
- 19. Sander LE, Davis MJ, Boekschoten MV, Amsen D, Dascher CC, Ryffel B, et al. Detection of prokaryotic mRNA signifies microbial viability and promotes immunity. Nature. 2011;474(7351):385–9. pmid:21602824
- 20. Woolcock P, Fabricant J. Duck hepatitis. Diseases of poultry. 2003;10:661–73.
- 21. Tseng CH, Knowles NJ, Tsai HJ. Molecular analysis of duck hepatitis virus type 1 indicates that it should be assigned to a new genus. Virus research. 2007;123(2):190–203. pmid:17067712
- 22. Ding C, Zhang D. Molecular analysis of duck hepatitis virus type 1. Virology. 2007;361(1):9–17. pmid:17300822
- 23. Gu CQ, Xie CQ, Hu XY, Zhang WP, Bi DR, Cheng GF. Cytokine gene expression in the livers of ducklings infected with duck hepatitis virus-1 JX strain. Poult Sci. 2012;91(3):583–91. pmid:22334733
- 24. Vanderven HA, Petkau K, Ryan-Jean KE, Aldridge JR Jr, Webster RG, Magor KE. Avian influenza rapidly induces antiviral genes in duck lung and intestine. Molecular immunology. 2012;51(3):316–24. pmid:22534314
- 25. Huang Y, Li Y, Burt DW, Chen H, Zhang Y, Qian W, et al. The duck genome and transcriptome provide insight into an avian influenza virus reservoir species. Nature genetics. 2013;45(7):776–83. pmid:23749191
- 26. Schröder M, Bowie AG. TLR3 in antiviral immunity: key player or bystander? Trends in immunology. 2005;26(9):462–8. pmid:16027039
- 27. Cunningham C, Campion S, Teeling J, Felton L, Perry VH. The sickness behaviour and CNS inflammatory mediator profile induced by systemic challenge of mice with synthetic double-stranded RNA (poly I:C). Brain, behavior, and immunity. 2007;21(4):490–502. pmid:17321719
- 28. Chen Y, Zhang Y, Huang Z, Xu Q, Zhu Z, Tong Y, et al. Molecular characterization, expression patterns, and subcellular localization of RIG-I in the Jinding duck (Anas platyrhynchos domesticus). Developmental and comparative immunology. 2013;41(4):766–71. pmid:23916689
- 29. Liu XY, Chen W, Wei B, Shan YF, Wang C. IFN-induced TPR protein IFIT3 potentiates antiviral signaling by bridging MAVS and TBK1. Journal of immunology. 2011;187(5):2559–68. pmid:21813773
- 30. Li Y, Li C, Xue P, Zhong B, Mao AP, Ran Y, et al. ISG56 is a negative-feedback regulator of virus-triggered signaling and cellular antiviral response. Proceedings of the National Academy of Sciences of the United States of America. 2009;106(19):7945–50. pmid:19416887