key: cord-0022151-2gph2phl
authors: Alqazlan, Nadiyah; Emam, Mehdi; Nagy, Éva; Bridle, Byram; Sargolzaei, Mehdi; Sharif, Shayan
title: Transcriptomics of chicken cecal tonsils and intestine after infection with low pathogenic avian influenza virus H9N2
date: 2021-10-14
journal: Sci Rep
DOI: 10.1038/s41598-021-99182-3
sha: 8e1e3d959f1385c411d36687acf488da5a737bb3
doc_id: 22151
cord_uid: 2gph2phl

Influenza viruses cause severe respiratory infections in humans and birds, triggering global health concerns and economic burden. Influenza infection is a dynamic process involving complex biological host responses. The objective of this study was to illustrate global biological processes in ileum and cecal tonsils at early time points after chickens were infected with low pathogenic avian influenza virus (LPAIV) H9N2 through transcriptome analysis. Total RNA isolated from ileum and cecal tonsils of non-infected and infected layers at 12-, 24- and 72-h post-infection (hpi) was used for mRNA sequencing analyses to characterize differentially expressed genes and overrepresented pathways. Statistical analysis highlighted transcriptomic signatures significantly occurring 24 and 72 hpi, but not earlier at 12 hpi. Interferon (IFN)-inducible and IFN-stimulated gene (ISG) expression was increased, followed by continued expression of various heat-shock proteins (HSP), including HSP60, HSP70, HSP90 and HSP110. Some upregulated genes involved in innate antiviral responses included DDX60, MX1, RSAD2 and CMPK2. The ISG15 antiviral mechanism pathway was highly enriched in ileum and cecal tonsils at 24 hpi. Overall, most affected pathways were related to interferon production and the heat-shock response. Research on these candidate genes and pathways is warranted to decipher underlying mechanisms of immunity against LPAIV in chickens.

Avian influenza viruses (AIVs) pose major public health threats and significant economic losses to the poultry industry 1, 2 . AIVs possess an error-prone RNA polymerase making them susceptible to reassortment, which occasionally results in the emergence of zoonotic viruses 3, 4 . Low pathogenic (LP) AIVs of subtype H9N2 are widespread pathogens of poultry. They are listed by the World Health Organization as a zoonotic influenza virus and ranked by Centers for Disease Control and Prevention (CDC) as potential pandemic viruses 5, 6 . A novel influenza A (H7N9) virus is likely to have acquired six viral segments from circulating avian H9N2 viruses 7 .

The subtype of the virus is a critical factor in understanding the host's ability to regulate the immune responses against AIV [8] [9] [10] [11] . LPAIVs principally replicate in the avian respiratory and gastrointestinal tract (GIT), causing mild signs of illness 12 . Replication of LPAIVs in the GIT disrupts the gut microbiota and dysregulates type I interferons (IFN) [13] [14] [15] . The GIT plays a critical role in immune homeostasis, balancing the protection of the host against invading pathogens and interacting with commensal microbiota [16] [17] [18] . The well-developed gut-associated lymphoid tissues in the GIT are the first line of defence against invading pathogens and consist of various lymphoid cells found in Peyer's patches, cecal tonsils and epithelial lining and lamina propria of the GIT 19 . Peyer's patches are located at the anti-mesenterial side of the chicken jejunum, and one Peyer's patch is consistently found in ileum at the proximal ileocecal transition 20 . Peyer's patches epithelium has specialized cells called M cells that overlay follicles of defined T and B cell areas. Cecal tonsils are located at the cecum-rectum junction and have a structure similar to Peyer's patches 20, 21 . Antigen recognition through M cells or by direct antigen sampling by macrophages and dendritic cells induce intestinal immune responses 22, 23 .

There has been significant interest in understanding how influenza viruses interact with their host. To this end, several studies have interrogated transcriptomics of host responses to LPAIV and highly pathogenic AIV [24] [25] [26] . These studies have revealed a complex network of immune responses initiated by avian influenza viruses, at cellular and tissue levels, in the respiratory tract 24, [27] [28] [29] [30] , ileum 8, 31 , dendritic cells 25 and chicken embryonic fibroblasts 32 .

RNA-seq data analysis. The average number of reads that passed the quality control was 23.7 and 25.5 million reads per sample for cecal tonsils and ileum, respectively. The average percentage of reads uniquely mapped to the chicken reference genome was 89.7% and 91.7% of the reads for cecal tonsils and ileum, respectively.

Global profiles of DE genes in chicken infected with low pathogenic AIV subtype H9N2. Transcriptomic changes were detectable in cecal tonsils and peaked at 24 hpi. Comparing the gene expression in cecal tonsil tissues between infected and non-infected groups, the highest number of DE genes was 24 hpi and reduced to near baseline at 72 hpi (Table 1 ; Fig. 1A ). The significant changes were also illustrated for DE genes with volcano plots (Fig. 2) .

At 12 hpi (Fig. 1A) , there were no DE genes between AIV-infected and non-infected chickens' cecal tonsil tissues (FDR < 5%). However, using FC-based significance (FC < 1.5), we found a downregulated gene (FGF19), which is involved in mitogen-activated protein kinase (MAPK)1/MAPK3 signaling and cytokine signaling in immune system pathways.

Changes in DE genes began in cecal tonsils at 24 hpi (Fig. 1A) . Ninety-five genes had a significant fold-change in expression (84 upregulated, 11 downregulated) ( Table 1 ). The fold-change of gene expression between infected and non-infected groups ranged from 7.27 to -3.41. The gene with the highest upregulation was a novel gene called T-complex protein 1 subunit gamma-like. This gene is an orthologue of turkey's CCT3 (Chaperonin Containing T-complex protein 1 subunit 3) gene and encodes for a chaperonin member containing TCP1 complex. T-complex protein 1 (TCP1) is a chaperonin class of protein involved in intracellular assembly and folding of various proteins. Specifically, this protein's gamma subunit plays a crucial role in folding and assembling cytoskeleton proteins, exploited by viruses during early viral infection. TCP1 is also a cytosolic HSP60 family protein.

Another gene with significant upregulation was the early endosome antigen 1-like, a novel long non-coding RNA (lncRNA). We also found upregulation of HSPs (HSP90AA1, HSPH1, HSPA8) and some genes involved in innate immune and antiviral responses, including IFN-inducible genes and ISGs (DDX60, IFI6, RSAD2, IFIT5,  MX1, OASL, CMPK2, RNF213, ERAP1, IFIH1, STAT1, DHX58, IFITM5 (interferon-induced transmembrane) and C1S (complement C1s)). The MX1 gene prevents the import of nuclear material into viral nucleocapsids, which is known to have a disruptive effect on influenza A viruses by disrupting lipid rafts of the virus. CMPK2 is involved in the differentiation of monocytes and is involved in metabolism. The ERAP1 gene is involved in class I major histocompatibility complex (MHC)-mediated antigen processing and presentation. The DNAJA1 gene is an important paralog of DNAJA4, and response to heat and protein folding are some of its related annotations (GO:0,009,408, GO:0,006,457). C1S was an upregulated gene in the present study and is involved in the innate immune system and regulation of complement cascade pathways. A novel chicken gene characterized as an orthologue to human USP18, was upregulated. This novel chicken gene is involved in interferon signaling, antiviral mechanisms by IFN-stimulated genes and ISG15. Another novel chicken gene, described as guanylate binding protein 1, was also upregulated and among its GO term was cellular response to interferon-gamma. Downregulated genes in cecal tonsils at 24 hpi included a novel gene (an orthologue of human SAA gene). This gene is expressed in granulocytes and involved in the biological process of acute-phase responses (GO:0,006,953, acute inflammatory response to infection) and the innate immune system pathway (R-GGA-168249). At 72 hpi, only HSPA5 had a significant upregulated expression (FDR < 5%) ( Fig. 1A ; Table 1 ). The FDR threshold was set to 10% to examine genes under a relaxed level of significance. Five HSPs were significantly different at this level. Additionally, one of these upregulated genes was CIDEC (with the greatest FC > 1.5). CIDEC (cell death-inducing DFFA (DNA fragmentation factor-alpha)-like effector c) is involved in regulating the apoptotic process. The DOP1B gene was among the results for both FC > 1.5 and FDR < 10% and is known to increase during responses to infections.

Transcriptomic changes were detected in the ileal tissue at 12 hpi and peak at 24 hpi. Differential gene expression in ileal tissue samples of infected chickens was detected as early as 12 hpi, and further increased at 24 hpi and then decreased 72 hpi ( Fig. 1B ; Table 1 ). This changing dynamic and the number of significant changes were somewhat different from the cecal tonsil samples; the number of DE genes at 72 hpi was maintained above ileum baseline. The differences in DE genes and changing dynamics for each time point post-infection were further illustrated in volcano plots, which give a more detailed display of the magnitude of changes in contrast to the measure of statistical significance (Fig. 2) .

In ileum at 12 hpi, only three genes were significantly upregulated (FC > 1.5). RNF213 is related to class I MHC-mediated antigen processing and presentation pathways and adaptive immune system pathways. TRANK1 is a protein-coding gene, and its GO annotations for molecular functions include protein binding and ATP (Adenosine Triphosphate) binding. RNF213 and TRANK1 have orthologues in humans. NCKAP5 is involved in the formation and modification of the microtubules. www.nature.com/scientificreports/ At 24 hpi, the number of gene expression changes in ileum increased substantially (Fig. 1B) . Ninety genes had significant fold-changes (76 genes upregulated, and 14 genes downregulated) (FDR < 5% and FC > 1.5; Table 1 ). The fold-change of gene expression between infected and non-infected groups ranged from 2.38 to − 1.41. The gene with the greatest significant upregulation was the early endosome antigen 1-like, a novel lncRNA. The significant upregulation of RNF213 and TRANK1 continued from 12-to 24-hpi time point. There was also augmented expression of antiviral factors, including innate immune responses, IFN-inducible genes and ISGs (IFIT5, IFI6, IFIH1 (MDA5), IFITM5, IFI27L2, STAT1, MX1, DHX58, DDX60, and OASL). The RSAD2 gene was also one of the top upregulated genes. GO terms for RSAD2 were related to (1) defence responses to viruses, (2) CD4 + αβT cell activation and differentiation, (3) negative regulation of protein secretion and viral genome replication and (4) positive regulation of Toll-like receptor (TLR) 7/9 signaling pathways and T-helper 2 cell cytokine production. The ZBTB32 gene was also among the significantly upregulated genes; its GO terms were related to negative regulation of transcription by RNA polymerase II. The ZBTB32 orthologue in humans is ZBTB16, which is involved in the adaptive immune system and class I MHC-mediated antigen processing and presentation pathways. Heat-shock protein genes were also among the top results of upregulated genes, including HSPH1, HSPA2, HSP90AA1, HSPB9, HSPA4L and HSPA8. The C1R gene was also upregulated. It is involved in complement activation and the classical antibody-mediated complement activation pathway. TLR3 was upregulated in this study. This gene encodes TLR 3, which recognizes double-stranded RNA and plays a vital role in pathogen recognition and activation of innate immunity.

Among the significantly downregulated genes in ileum at 24 hpi were GNLY, CD3D, CST7, PTPN7, WAS and XCL1. GNLY, CD3D and CST7 are involved in the innate immune system. The PTPN7 annotation was cytokine signaling in the immune system, and WAS is involved in the Fc-gamma receptor-dependent phagocytosis pathway. XCL1 is involved in chemokine-mediated signaling pathways, G protein-coupled receptor signaling pathway, and cellular responses to IFN-gamma, IL-1 and tumour necrosis factor.

Of the 37 DE genes in ileum of infected chickens at 72 hpi, 25 genes had significant fold-changes (Table 1) . HSPs were in the top results (HSPH1 (HSP110), HSP90AA1 (HSP90), HSPA4L, HSPA5 and HSPA8 (HSP70)). www.nature.com/scientificreports/ Additionally, PDK4, CHAC1, DNAJA4 and DNAJA1 were upregulated. In mice with severe influenza, inhibition of PDK4 using a therapeutic agent results in prevention of multiorgan failure 39 . CHAC1 gene annotations included the intrinsic apoptotic signaling pathway in response to endoplasmic reticulum stress, which usually results from the accumulation of unfolded or misfolded proteins in the lumen of the endoplasmic reticulum lumen (GO:0,070,059), and negative regulation of the Notch signaling pathway (GO:0,045,746). Like cecal tonsils results, DNAJA4 and its paralog DNAJA1 gene were also upregulated in ileum at 72 hpi. The DNAJA4 gene has related annotations, including unfolded protein binding and HSP binding (GO:0,051,082, GO:0,031,072). TGIF1 gene was upregulated and involved in signaling by the transforming growth factor (TGF)-β receptor complex pathway. The genes that were most downregulated in ileum at 72 hpi included P2RY4, which is involved in the G protein-coupled receptor signaling pathway. ELF3 was also downregulated, and one of its gene ontogeny biological processes terms was inflammatory response to infection (GO:0,006,954). ELF1 is a protein encoded by the ELF1 gene, which is a paralog of ELF3 gene and regulates broad antiviral responses distinct from the type I IFN response 40 .

annotation analysis of Reactome pathways using the PANTHER overrepresentation test among significantly upregulated genes resulted in three statistically significant (FDR < 5%, Fisher's exact test) Reactome pathways in cecal tonsils and ileum at 24 hpi. In both tissues, the highest enriched pathway was the ISG15 antiviral mechanism (Table 2) . Fig. 3B . The GO terms of the molecular functions for the upregulated genes included protein folding chaperone, single-stranded RNA binding and HSP binding.

In ileum at 24 hpi, the upregulated genes were classified into 30, 21 and one functional groups (FDR < 5%) of biological processes, molecular functions and cellular components, respectively (Supplementary Tables 9, 10 and 11). The top 10 results of enriched biological processes are shown in Fig. 3A . The main GO categories of the biological processes were regulation of PRR signaling pathways, positive regulation of cytokine production (e.g. IFN-β), negative regulation of viral process (e.g. negative regulation of viral genome replication) and response to stress (e.g. defense response to virus). The top 10 results of enriched molecular functions are shown in Fig. 3B . The GO terms of the molecular functions included protein folding chaperone, double-and single-stranded RNA binding, chaperone binding and unfolded protein binding. Figure 3C shows the cellular component (cytosol) as the only enriched GO term relevant to ileum at 24 hpi.

In ileum at 72 hpi, the DE upregulated genes were classified into 19 biological processes, 19 molecular functions and one cellular component at FDR < 5% (Supplementary Tables 12, 13 and 14) according to the GO project, respectively. The top 10 results of enriched biological processes are shown in Fig. 3A . The main biological Table 2 . Functional annotation analysis of Reactome pathways using PANTHER. Overrepresentation analysis was performed on PANTHER. The analysis was performed on upregulated genes of significant gene changes in each tissue at each time point by filtering genes with a fold change of + /− 1.5 and significant P-value of False Discovery Rate (FDR) controlled at 5%. IFN interferon, ISG IFN-stimulated genes. www.nature.com/scientificreports/ www.nature.com/scientificreports/ processes were negative regulation of inclusion body assembly, negative regulation of transcription from RNA polymerase II promoter in response to stress and protein refolding. Figure 3B presents the top 10 enriched molecular functions, including C3HC4-type RING (Really Interesting New Gene) finger domain binding, protein folding chaperone, misfolded protein binding, chaperone binding and HSP binding. The cellular component (cytosol) was the only enriched GO term in ileum at 72 hpi (Fig. 3C ).

Immunity against AIV is the result of an orchestrated effort between innate and adaptive immune responses to this virus. Transcriptomic studies have been carried out in the GIT of chickens during infection with various subtypes of influenza A viruses. Infection with H5N1 or H5N2 in chickens results in differential expression of genes associated with innate immune responses in ileum 8 . Also, transcriptome analysis of ileum from birds infected with high (H5N1) and low (H5N2) pathogenic influenza viruses has revealed very different IFITM responses in ducks and chickens 31 . Yet, there is no comprehensive understanding of the mechanisms of immune response to LPAIV, such as H9N2, in the GIT. The present study was designed to evaluate the global gene expression changes in cecal tonsils and ileum of chickens after infection with H9N2 AIV. The induced expression patterns of different genes in ileum and cecal tonsils of AIV-infected chickens were revealed with some important observations. Comparing the gene expression profiles of cecal tonsils and ileum, we observed some shared and unique responses to AIV infection. At 24 and 72 hpi, the comparison of differentially expressed genes showed that there were no genes displaying an opposite expression pattern between the two tissues and between the time points post-infection (Supplementary Fig. 2A-D) . None of the sets resulted in any pathway with FDR < = 5%, except the upregulated genes in ileum at 24 hpi. The most enriched pathways were the regulation of gene expression by hypoxia-inducible factor (HIF) pathway (R-GGA-1234158) and the TRAF6-mediated interferon regulatory factor (IRF7) activation pathway (R-GGA-933541). The mechanism of viral activation of the HIF-1 pathway is that influenza A virus infection causes impaired proteasome function, resulting in HIF-1α accumulation, and decreases expression of factor inhibiting HIF-1, further boosting HIF-1 activity 41 . Nuclear translocation of HIF-1α induced by influenza A infection is crucial to pro-inflammatory cytokines production, and deficiency of HIF-1α in lung epithelial cells enhances autophagy, facilitating influenza A virus replication 42, 43 . Activation of IRF7 is triggered by TLR7 recognition of RNA released from the influenza virus, which is followed by the production of type I IFNs. Moreover, TRAF6-mediated IRF7 activation establishes innate immune responses and the absence of TRAF6 ensues enhanced viral replication and a significant reduction in IL-6 and type I IFNs production after infection with RNA virus 44 .

In the present study, RNF213 was upregulated gene in ileum at 12 and 24 hpi and cecal tonsils at 24 hpi. The Rnf213 gene was identified as highly expressed among a cluster of ISGs with known antiviral activity in a mouse model 45 . The model revealed that the heterogeneity of influenza replication from cell to cell is not derived by cell type. Also, the cells with no or low viral replication have high induction of the Rnf213 gene 45 . Additionally, a low abundance of virus transcripts is associated with the host innate response (response to type I IFN) gene cluster, including the RNF213 gene, which is significantly highly expressed in response to influenza infection 46 . Further, a transcriptomic analysis has revealed new genes and networks in response to H5N1 infection in ducks; among them, the RNF213 gene is expressed differentially in the brain post-infection 47 .

Here, we report that a novel gene called early endosome antigen 1-like and identified as a lncRNA had significant upregulation in cecal tonsils and ileum at 24 hpi. Although little is known about lncRNAs, a lncRNA is upregulated due to viral delivery and is required to induce antiviral effects by promoting an increase in IFN production 48 . Furthermore, an evolutionarily conserved role for lncRNAs has been suggested, as conserved sequences are found to define virus-specific effector and memory CD8 + T cells 49 . Early endosome antigen 1 (EEA1), a protein-coding gene, is involved in vesicular trafficking and is affected by bacterial infections 50, 51 . Intracellular pathogens target molecular factors, including EEA1, and inhibit its recruitment, triggering phagosomal maturation arrest 50, 52 . Influenza A viruses benefit from EEA1 to infect human cells; following internalization of virus particles in dendritic cells, the influenza virus traffic through EEA1 + early endosomes to gain access to the cytoplasm 53 . Chicken EEA1 is a coding orthologue of human EEA1. It is hypothesized that lncRNA is involved in competing for endogenous RNA (ceRNA), which could regulate a protein-coding gene by sponging up microRNA 54 . The infected cells may increase early endosome antigen 1-like expression to limit viral entry to cells in the current study.

DExD/H-box helicases, such as DDX3, have been involved as sensors in innate antiviral immunity [55] [56] [57] [58] . DDX60 is involved in RIG-I-dependent and independent antiviral responses 59 . Several DEAD/DEAH-box RNA helicases are hijacked by RNA viruses in infected cells to facilitate their replication [60] [61] [62] [63] [64] . Chicken DDX60 and DHX58 have orthologues in humans. In the present study, two IFN-inducible cytoplasmic helicases were upregulated in chicken GIT post-infection: DDX60 (DExD/H-box helicase 60) and DHX58 (DExH-box helicase 58, also known as LGP2 (laboratory of genetics and physiology 2)). Our observations supported the role of DExD/H-box helicases in innate antiviral immunity and their manipulation by viruses. DDX60 upregulation started at 12 hpi in ileum but not in cecal tonsils, which then reached significant upregulation at 24 hpi in both tissues, and then subsided at 72 hpi. This gene expression may imply a broader function of chicken DExD/H-box helicases and provide a deeper understanding of immune mechanisms and pathogenesis of AIV in chicken GIT.

Heat shock proteins shared across Archea, bacteria and eukaryotes, are associated with cellular injury. Expression of HSPs is elevated to protect cells under stress and is involved in protein folding, the immune system and antiviral response. However, viruses lack HSPs and depend on host HSPs for their protein folding 65 . Therefore, viruses can hijack HSPs, including hsp40, hsp70 and hsp90, to increase viral replication 66 . Exogenous administration of HSPs can enhance immune responses in cancer and infectious diseases by activation of protective T cell responses 67, 68 . HSPs can also interact with various viral proteins; for example, HSPA8 can interact with www.nature.com/scientificreports/ influenza virus protein M1. This interaction inhibits the nuclear export of matrix protein 1 and nucleoprotein and subsequently inhibits viral assembly 69 . Upregulation of HSPs has been reported in the chicken respiratory tract 27 . In the present study, we found that HSPs were upregulated significantly at 24 and 72 hpi in ileum and cecal tonsils of AIV-infected chickens. Targeting HSPs could provide a platform for prophylactic or therapeutic strategies to manipulate immune responses against AIV in poultry. Viruses also exploit cytoskeleton proteins during early viral replication 70, 71 . TCP1 is a chaperonin and a cytosolic HSP60 family protein 72 . The gamma subunit of TCP1 plays a vital role in the folding and assembling of cytoskeleton proteins 73, 74 . Chicken TCP1 has a human orthologue-section of the gene that codes for the gamma-like subunit. T-complex protein 1 subunit gamma-like, a novel gene in the chicken genome, is a paralogue of chicken TCP1. In the present study, we found the most upregulation of the T-complex protein 1 subunit gamma-like gene in cecal tonsils at 24 hpi. This unique gene upregulation in cecal tonsils may signal this gene's employment by H9N2 AIV in the current study for its purposes in protein folding and assembly.

We found that MX1 gene was upregulated in ileum and cecal tonsils. This may draw a link to an anti-viral response in chicken cecal tonsils to AIV infection. MX1 protein inhibits the import of nuclear material into viral nucleocapsids, which is known to have a disruptive effect on influenza A viruses by disrupting lipid rafts of the virus. Other transcriptomic studies in poultry have also shown upregulation of this gene in repertory tract and ileum 8, 24, 27 .

IFITM is a family of genes known to have a role in limiting influenza infection 75 . Transcriptomic analysis shows that chickens mount a weak IFITM response in ileum post-infection with LPAIV H5N2 31 . However, the findings of our study showed upregulation of IFITM5 in cecal tonsils and ileum at 24 hpi. This discrepancy of IFITM response may be because of the different subtypes used.

The results of the functional analyses of the DE genes were related to the immune responses to influenza infection. GO terms and Reactome pathways results were almost exclusively associated with response to viral infection. In cecal tonsils and ileum at 24 hpi, one of the highest enriched pathways was the ISG15 antiviral mechanism ( Supplementary Fig. 1 ). IFN-induced ISG15 targets the non-structural 1 (NS1A) protein of the influenza A virus, causing a loss of function of the NS1A protein and the inhibition of influenza A virus replication in virus-infected cells 76 . Additionally, ISG15 plays various roles in the defence against viral infections and the activation of immune system cells such as lymphocytes, monocytes, and natural killer cells 77 . Interestingly, the NS1A protein of influenza A viruses is responsible for inhibiting host immune responses by limiting production of IFNs and, therefore, antiviral effects of IFN-induced proteins 78 .

In conclusion, our study illustrated the differential expression of several innate immune system genes following AIV infection in ileum and cecal tonsils. The results of the present study revealed that there is some degree of similarity between immune responses in GIT and those induced in the respiratory tract, although further research is required to determine whether there are spatial and temporal differences in gene expression between the gastrointestinal and respiratory tracts. Our study highlighted some of the DE genes that are known to be exploited by the influenza virus to support viral replication. Some of the DE genes have been consistently identified in chicken LPAIV studies, hinting that they may be the best candidates for future research. One important finding was the enriched antiviral pathway of ISG15. ISG15 plays a critical role in innate responses, and future research studying this mechanism might provide a platform for strategies against AIV in poultry.

Experimental design. This study included two main factors: treatment (challenged versus nonchallenged) and time (three time points post-infection), resulting in six groups. Each group contained six biological replicates. A total of 36 one-day-old specific pathogen-free White Leghorn layers were purchased from the Canadian Food Inspection Agency (Ottawa, Canada) and housed in the isolation facility at the Ontario Veterinary College at the University of Guelph. All experimental procedures were approved by the University of Guelph Animal Care Committee and conducted according to specifications of the Canadian Council on Animal Care. Experiments in the manuscript followed the recommendations in the ARRIVE guidelines.

Twenty-one days after hatching, 18 chickens in the challenged group were inoculated via oculo-nasal and oral routes with 250 μL of 3.1 × 10 7 TCID 50 /mL of LPAIV H9N2. Eighteen chickens in the nonchallenged group were inoculated via the same route with 200 μL of phosphate-buffered saline. The ileal samples at proximal ileocecal transition and cecal tonsils were collected from six chickens per time point at 12, 24, and 72 h post-infection (hpi) per treatment. The collected samples were transferred into tubes containing 1 mL of RNAlater solution (Invitrogen, Burlington, ON, CAN) for RNA stabilization and storage for later processing. The above time points were chosen that coincides with induction of innate responses to the virus.

A/TK/IT/13VIR1864-45/2013 (H9N2) from the Istituto Zooprofilattico Sperimentale delle Venezie (IZSVe), Italy, was used in this study. The virus was propagated in 10-day-old embryonated specific pathogen-free chicken eggs. After 72 h of incubation at 37 °C, eggs were refrigerated at 4 °C overnight. Allantoic fluid was collected and purified by centrifuging at 400 × g for 5 min at 4 °C and then stored at -80 °C until further use. The propagated virus titer was determined with 50% tissue culture infectious dose (TCID 50 ) on Madin-Darby canine kidney (MDCK) cells.

Extraction, library preparation and RNA sequencing. Total RNA was extracted using the RNeasy Mini kit (Qiagen, Toronto, ON, CAN) according to the manufacturer's instructions. Library construction, quality control testing and sequencing were performed by Novogene (Sacramento, USA). Briefly, quantification and quality control testing were performed on 1% agarose gels, the NanoPhotometer spectrophotometer (IMPLEN, CA, USA) and the RNA Nano 6000 Assay Kit in a Bioanalyzer 2100 system (Agilent Technologies, CA, USA). A www.nature.com/scientificreports/ total amount of 1 μg of RNA per sample was used for library preparation using a NEBNext Ultra RNA Library Prep Kit for Illumina (New England Biolabs, USA). Library quality was assessed on the Agilent Bioanalyzer 2100 system. The clustering of the index-coded samples was performed on a cBot Cluster Generation System using a PE Cluster Kit cBot-HS (Illumina). cDNA libraries were sequenced on an Illumina HiSeq-4000 platform, and 150 base pair paired-end reads were generated.

RNAseq data analysis interpretation. RNA-seq analysis was performed on the Trimmomatic-STAR-RSEM-DESeq2 pipeline previously established 79 . Raw reads were processed for quality control. Clean data were obtained based on Phred score (a quality measure to assess the accuracy of a sequencing) by trimming adapters and nucleotides with a Phred score of less than 30 at the beginning and end of the reads and discarding nucleotides with a Phred score of less than 20 in the window of five nucleotides using Trimmomatic 80 . The minimum length of surviving reads was set at 36 nucleotides. All downstream analyses were based on clean data with high quality.

Reads were mapped to a Gallus gallus reference genome (GRCg6a, release 98) using Spliced Transcripts Alignment to a Reference (STAR) (version 2.7.0a) 81 . The number of reads per gene was quantified by RNA-Seq by Expectation-Maximization (RSEM) 82 . RSEM output files were used in DESeq2 (version 1.24.0) to calculate differentially expressed (DE) genes by comparing challenge group versus control group for each tissue per time point 83 . Genes with an absolute fold-change (FC) of more than a 1.5 (|FC|> 1.5; |log 2 FC|> 0.584) and with a significant p-value when False Discovery Rate (FDR) was controlled at 5% were considered DE. VennDiagram package in R was used to compare DE genes between cecal tonsils and ileum at 24 and 72 h time points 84 . 

The datasets generated and analyzed during the current study are available in SRA database, BioProject ID PRJNA735215.

Received: 28 November 2020; Accepted: 1 September 2021

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Transcriptomic analyses reveal new genes and networks response to H5N1 influenza viruses in duck (Anas platyrhynchos)

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Visualization of early influenza A virus trafficking in human dendritic cells using STED microscopy

Analysing the relationship between lncRNA and protein-coding gene and the role of lncRNA as ceRNA in pulmonary fibrosis

DExD/H-box RNA helicases as mediators of anti-viral innate immunity and essential host factors for viral replication

DDX3 functions in antiviral innate immunity through translational control of PACT

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DEAD-box helicases: sensors, regulators, and effectors for antiviral defense

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We would like to acknowledge the isolation unit staff at the Ontario Veterinary College, University of Guelph, for their help with the care and housing of chickens. Funding was provided in part by Agriculture and Agri-Food Canada. The Ontario Ministry of Agriculture Food and Rural Affairs, the Natural Sciences and Engineering Research Council of Canada, Egg Farmers of Canada, Chicken Farmers of Saskatchewan, and the Canadian Poultry Research Council provided funding as well. This research was also supported in part by the University of Guelph's Food from Thought initiative and the Canada First Research Excellence Fund. We are also thankful for the kind support from the Istituto Zooprofilattico Sperimentale delle Venezie, Italy, by providing the virus used in this study.

The authors declare no competing interests.

The online version contains supplementary material available at https:// doi. org/ 10. 1038/ s41598-021-99182-3.Correspondence and requests for materials should be addressed to S.S.Reprints and permissions information is available at www.nature.com/reprints.Publisher's note Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.