Influenza A Virus Infection in Domestic Ferrets.

Induction of cyclophilin A by influenza A virus infection facilitates group A Streptococcus coinfection.

Viruses and hosts have coevolved for millions of years, leading to the development of complex host–pathogen interactions. Influenza A virus (IAV) causes severe pulmonary pathology and is a recurrent threat to human health. Innate immune sensing of IAV triggers a complex chain of host responses. IAV has adapted to evade host defense mechanisms, and the host has coevolved to counteract these evasion strategies. However, the molecular mechanisms governing the balance between host defense and viral immune evasion is poorly understood. Here, we show that the host protein DEAD-box helicase 3 X-linked (DDX3X) is critical to orchestrate a multifaceted antiviral innate response during IAV infection, coordinating the activation of the nucleotide-binding oligomerization domain-like receptor with a pyrin domain 3 (NLRP3) inflammasome, assembly of stress granules, and type I interferon (IFN) responses. DDX3X activated the NLRP3 inflammasome in response to WT IAV, which carries the immune evasive nonstructural protein 1 (NS1). However, in the absence of NS1, DDX3X promoted the formation of stress granules that facilitated efficient activation of type I IFN signaling. Moreover, induction of DDX3X-containing stress granules by external stimuli after IAV infection led to increased type I IFN signaling, suggesting that NS1 actively inhibits stress granule–mediated host responses and DDX3X-mediated NLRP3 activation counteracts this action. Furthermore, the loss of DDX3X expression in myeloid cells caused severe pulmonary pathogenesis and morbidity in IAV-infected mice. Together, our findings show that DDX3X orchestrates alternate modes of innate host defense which are critical to fight against NS1-mediated immune evasion strategies during IAV infection.

New Look at an Old Problem: Bacterial Superinfection after Influenza

Influenza A virus (IAV) is a respiratory pathogen with a segmented negative-sense RNA genome that can cause epidemics and pandemics. The host factors required for the complete IAV infectious cycle have not been fully identified. Here, we examined three host factors for their contributions to IAV infectivity. We performed CRISPR-mediated knockout of cytidine monophosphate N-acetylneuraminic acid synthetase (CMAS) as well as CRISPR-mediated overexpression of beta-1,4 N-acetylgalactosaminyltransferase 2 (B4GALNT2) and adenosine deaminase acting on RNA 1 (ADAR1) in the human bronchial epithelial A549 cell line and evaluated the impact on IAV and other RNA viruses. We confirmed that knockout of CMAS or overexpression of B4GALNT2 restricts IAV infection by diminishing binding to the cell surface but has no effect on vesicular stomatitis virus infection. Although ADAR1 overexpression does not significantly inhibit IAV replication, it has a pro-viral effect with coxsackie B virus (CVB) infection. This pro-viral effect is not likely secondary to reduced type I interferon (IFN) production, as the induction of the IFN-stimulated genes ISG15 and CXCL10 is negligible in both parent and ADAR1-overexpressing A549 cells following CVB challenge. In contrast, ISG15 and CXCL10 production is robust and equal for parent and ADAR1-overexpressing A549 cells challenged with IAV. Taken together, these data provide insights into how host factors can be further explored to understand the dynamics of pro- and anti-viral factors.IMPORTANCEInfluenza A virus (IAV) remains a global threat due to its ability to cause pandemics, making the identification of host factors essential for developing new antiviral strategies. In this study, we utilized CRISPR-based techniques to investigate host factors that impact IAV infectivity. Knockout of CMAS, a key enzyme in sialic acid biosynthesis, significantly reduced IAV binding and infection by disrupting sialic acid production on the cell surface. Overexpression of B4GALNT2 had similar effects, conferring resistance to IAV infection through diminished cell-surface binding. Overexpression of ADAR1, known for its role in RNA editing and immune regulation, impacted IAV replication minimally but enhanced coxsackie B virus replication. Such findings reveal the diverse roles of host factors in viral infection, offering insights for targeted therapeutic development against IAV and other pathogens.

Influenza virus is a member of Orthomyxoviridae, and infection of influenza virus can cause severe morbidity and mortality in the elderly and children. Influenza A viruses are enveloped and have two surface glycoproteins, hemagglutinin (HA) and neuraminidase (NA). Both of HA and NA undergo antigenic shift and antigenic drift. Antibody to HA is the most important determinant of immunity because it can neutralize the infectivity of influenza virus. Although anti-NA antibodies do not neutralize virus infectivity, they appear to modify the disease and reduce both pulmonary virus titer and the extent of lung lesions. Therefore, antigenic variability of the NA protein should also be considered when analyzing the epidemic impact of influenza virus and predicting newly emerging viruses. However, limited information is available concerning the molecular change of the influenza NA genes. Analysis of NA gene is particularly important since the use of influenza NA inhibitors that target the highly conserved catalytic site of the enzyme. In order to understand the variation of NA gene of influenza A (H3N2) virus in northern Taiwan, 43 strains of clinical isolates in Taipei during 2000-2004 were collected for this study. The result indicated that the amino acid variation rate of NA was about 0.5% per year. As compared with the A/Moscow/10/99 vaccine strain, amino acid changes within at least one of the seven NA antigenic determinants (I-VII) were found in approximate half of the isolates (20/43) and the most common changes were at position 332, 401, 431 and 432. Only one amino acid change (D151G) was observed in the catalytic site of NA. All isolates contained the seven conserved asparagine-linked glycosylation sites found in the NA of the progenitor A/Hong Kong/8/68 strain. In addition, most strains (38/43) had the new glycosylation sites at positions 93 and 329. To understand whether there is gene reassortment recently, we also analyzed the evolutionary relationship of these isolates. It appears that no HA/NA reassortment was found. Variation of plaque size was observed in the plaque assay. After purification of virus, a small-plaque virus strain (NA-) was obtained and a 586 nucleotide deletion (303-888nt) of NA gene was found. Although the deficiency of NA enzyme activity, it still can grow in MDCK cell. However, the virus yield was 45-fold less than wild-type when low MOI (10-5) was used. The receptor-binding ability of the defective virus was low but no compensatory substitutions in the HA gene were found. TamifluTM, a kind of anti-influenza drug, did not influence on NA- virus in vitro. Thus, our results suggest that NA activity may not be essential for influenza A virus growth.

High throughput proteomics and transcriptomics has provided a platform to further understand viral – host interaction. This provides a window into the host proteome and transcriptome with and without infection. This leads to identification of potential biomarkers, understanding IAV pathogenesis and also drawing a comparison of how hosts respond to viral infection. This thesis used two independent high throughput approaches to explore the proteome and transcriptome of samples from hosts (in vitro and in vivo) infected with influenza A virus (IAV) compared to samples from hosts (in vitro and in vivo) non-infected with IAV. The independent high throughput approaches used were; proteomics on a Q-Exactive platform and transcriptomics on a MinION sequencer. These approaches were used to further understand IAV infection in these different hosts and secondly to explore and search further for a potential biomarker for the diagnosis of IAV and potential drug targets. To our knowledge, this is the first study that has used high throughput approaches to analyses samples from different hosts. This allowed for comparison across hosts but also provides vast amounts of data that are reliable and consistent. A549 cells that were mock-infected and IAV- infected were subjected to the Q-Exactive platform and MinION sequencing. This provided insight into the in vitro host-viral interaction on a cellular level. For the first time, showed the potential of MinION sequencing as a method for understanding the viral-host interaction of IAV infected cells and identifying potential biomarkers. This highlighted transcripts such as NUP54, RBM42, HPGD, GCLC, ANPEP, AKAP13, RACGAP1, CREB1, MAN2B1 and PRKCI. These transcripts were identified by bioinformatic analysis as host factors that play a crucial role in replication of IAV in the host. The corresponding proteins to these transcripts were also identified by proteomics. To better understand IAV in hosts, in vivo, Non-human primates (NHP) were infected with IAV and the broncho-alveolar fluid (BALF) was collected and compared to BALF from naive NHP. After analysis on the Q-Exactive platform, the results obtained drew parallels on a cellular level to that observed in vitro models. Proteins such as; DDX58, EIF3A, HSP90AA1, MAPK1, MX1 and STAT1 involved in the “replication of IAV” were highlighted. In addition to the cellular changes, the NHP studies provided insight into an immune response similar to that observed in humans following IAV infection. This provided an added dimension in understanding IAV infection. Finally, nasopharyngeal aspirates (NAs) from humans IAV- infected and IAV non-infected from three different cohorts (Alder Hey Children’s hospital (AHCH), Liverpool, Great Ormond Street Hospital (GOSH), London and Institute Pasteur Dakar (IPD)) were analysed on the Q-Exactive platform. This provided a full circle loop to compare if the changes observed in vitro model – A549 cells and in vivo model-NHP were relatable back to humans. Proteins identified in vitro and in vivo studies were concordant with proteins identified in the human NAs. These proteins include; COPA, STAT1, TUBB and HSPB1. Additionally, three proteins were identified in human NAs across all three cohorts; BPIFA1/SPLUNC1, Lactotransferrin and Fibrinogen A, B and G. These proteins play crucial roles in elucidating IAV infection in the host. This study presents the first time these proteins have been highlighted using label-free Mass spectrometry in human NAs across three cohorts from different geographical locations. This thesis illustrates how proteomic analysis of IAV-infected samples compared to non-infected samples can be used to identify markers that may serve as potential diagnostic indicators for IAV infection.

Alveolar macrophages (AM) play pivotal roles in modulating host defense, pulmonary inflammation, and tissue injury following respiratory viral infections. However, the transcriptional regulation of AM function during respiratory viral infections is still largely undefined. Here we have screened the expression of 84 transcription factors in AM in response to influenza A virus (IAV) infection. We found that the transcription factor PPAR-γ was downregulated following IAV infection in AM through type I interferon (IFN)-dependent signaling. PPAR-γ expression in AM was critical for the suppression of exaggerated antiviral and inflammatory responses of AM following IAV and respiratory syncytial virus (RSV) infections. Myeloid PPAR-γ deficiency resulted in enhanced host morbidity and increased pulmonary inflammation following both IAV and RSV infections, suggesting that macrophage PPAR-γ is vital for restricting severe host disease development. Using approaches to selectively deplete recruiting monocytes, we demonstrate that PPAR-γ expression in resident AM is likely important in regulating host disease development. Furthermore, we show that PPAR-γ was critical for the expression of wound healing genes in AM. As such, myeloid PPAR-γ deficiency resulted in impaired inflammation resolution and defective tissue repair following IAV infection. Our data suggest a critical role of PPAR-γ expression in lung macrophages in the modulation of pulmonary inflammation, the development of acute host diseases, and the proper restoration of tissue homeostasis following respiratory viral infections.IMPORTANCE Respiratory viral infections, like IAV and respiratory syncytial virus (RSV) infections, impose great challenges to public health. Alveolar macrophages (AM) are lung-resident immune cells that play important roles in protecting the host against IAV and RSV infections. However, the underlying molecular mechanisms by which AM modulate host inflammation, disease development, and tissue recovery are not very well understood. Here we identify that PPAR-γ expression in AM is crucial to suppress pulmonary inflammation and diseases and to promote fast host recovery from IAV and RSV infections. Our data suggest that targeting macrophage PPAR-γ may be a promising therapeutic option in the future to suppress acute inflammation and simultaneously promote recovery from severe diseases associated with respiratory viral infections.

DAI Senses Influenza A Virus Genomic RNA and Activates RIPK3-Dependent Cell Death.

Influenza A virus (IAV) is the causative agent of flu disease that results in annual epidemics and occasional pandemics. IAV alters several signaling pathways of the cellular host response in order to promote its replication. Therefore, some of these pathways can serve as targets for novel antiviral agents. Here, we show that c-Jun NH2-terminal kinase (JNK)-interacting protein 4 (JIP4) is dynamically phosphorylated in IAV infection. The lack of JIP4 resulted in higher virus titers, with significant differences in viral protein and mRNA accumulation as early as within the first replication cycle. In accordance, decreased IAV titers and protein accumulation were observed during the overexpression of JIP4. Strikingly, the antiviral function of JIP4 does not originate from modulation of JNK or p38 mitogen-activated protein kinase (MAPK) pathways or from altered expression of interferons or interferon-stimulated genes but rather originates from a direct reduction of viral polymerase activity. Furthermore, the interference of JIP4 with IAV replication seems to be linked to the phosphorylation of the serine at position 730 that is sufficient to impede the viral polymerase. Collectively, we provide evidence that JIP4, a host protein modulated in IAV infection, exhibits antiviral properties that are dynamically controlled by its phosphorylation at S730. IMPORTANCE Influenza A virus (IAV) infection is a world health concern, and current treatment options encounter high rates of resistance. Our group investigates host pathways modified in IAV infection as promising new targets. The host protein JIP4 is dynamically phosphorylated in IAV infection. JIP4 absence resulted in higher virus titers and viral protein and mRNA accumulation within the first replication cycle. Accordingly, decreased IAV titers and protein accumulation were observed during JIP4 overexpression. Strikingly, the antiviral function of JIP4 does not originate from modulation of JNK or p38 MAPK pathways or from altered expression of interferons or interferon-stimulated genes but rather originates from a reduction in viral polymerase activity. The interference of JIP4 with IAV replication is linked to the phosphorylation of serine 730. We provide evidence that JIP4, a host protein modulated in IAV infection, exhibits antiviral properties that are dynamically controlled by its phosphorylation at S730.

Influenza A viruses (IAV), members of the Orthomyxoviridae, cover a wide host spectrum comprising a plethora of avian and, in comparison, a few mammalian species. The viral reservoir and gene pool are kept in metapopulations of aquatic wild birds. The mammalian-adapted IAVs originally arose by transspecies transmission from avian sources. In swine, horse and man, species-adapted IAV lineages circulate independently of the avian reservoir and cause predominantly respiratory disease of highly variable severity. Sporadic outbreaks of IAV infections associated with pneumonic clinical signs have repeatedly occurred in marine mammals (harbour seals [Phoca vitulina]) off the New England coast of the U.S.A. due to episodic transmission of avian IAV. However, no indigenous marine mammal IAV lineages are described. In contrast to marine mammals, avian- and equine-derived IAVs have formed stable circulating lineages in terrestrial carnivores: IAVs of subtype H3N2 and H3N8 are found in canine populations in South Korea, China, and the U.S.A. Experimental infections revealed that dogs and cats can be infected with an even wider range of avian IAVs. Cats, in particular, also proved susceptible to native infection with human pandemic H1N1 viruses and, according to serological data, may be vulnerable to infection with further human-adapted IAVs. Ferrets are susceptible to a variety of avian and mammalian IAVs and are an established animal model of human IAV infection. Thus, a potential role of pet cats, dogs and ferrets as mediators of avian-derived viruses to the human population does exist. A closer observation for influenza virus infections and transmissions at this animal-human interface is indicated.

Human nasal epithelial cells derived from multiple subjects exhibit differential responses to H3N2 influenza virus infection in vitro

The ubiquitous presence of cell-surface sialic acid (SIA) has complicated efforts to identify specific transmembrane glycoproteins that function as bone fide entry receptors for influenza A virus (IAV) infection. The C-type lectin receptors (CLRs) DC-SIGN (CD209) and L-SIGN (CD209L) enhance IAV infection however it is not known if they act as attachment factors, passing virions to other unknown receptors for virus entry, or as authentic entry receptors for CLR-mediated virus uptake and infection. Sialic acid-deficient Lec2 Chinese Hamster Ovary (CHO) cell lines were resistant to IAV infection whereas expression of DC-SIGN/L-SIGN restored susceptibility of Lec2 cells to pH- and dynamin-dependent infection. Moreover, Lec2 cells expressing endocytosis-defective DC-SIGN/L-SIGN retained capacity to bind IAV but showed reduced susceptibility to infection. These studies confirm that DC-SIGN and L-SIGN are authentic endocytic receptors for IAV entry and infection.

Backgroundp53 is a tumor suppressor that contributes to the host immune response against viral infections in addition to its well-established protective role against cancer development. In response to influenza A virus (IAV) infection, p53 is activated and plays an essential role in inhibiting IAV replication. As a transcription factor, p53 regulates the expression of a range of downstream responsive genes either directly or indirectly in response to viral infection. We compared the expression profiles of immune-related genes between IAV-infected wild-type p53 (p53WT) and p53-deficient (p53KO) mice to gain an insight into the basis of p53-mediated antiviral response.Methodsp53KO and p53WT mice were infected with influenza A/Puerto Rico/8/1934 (PR8) strain. Clinical symptoms and body weight changes were monitored daily. Lung specimens of IAV-infected mice were collected for analysis of virus titers and gene expression profiles. The difference in immune-related gene expression levels between IAV-infected p53KO and p53WT mice was comparatively determined using microarray analysis and confirmed by quantitative real-time reverse transcription polymerase chain reaction.Resultsp53KO mice showed an increased susceptibility to IAV infection compared to p53WT mice. Microarray analysis of gene expression profiles in the lungs of IAV-infected mice indicated that the increased susceptibility was associated with significantly changed expression levels in a range of immune-related genes in IAV-infected p53KO mice. A significantly attenuated expression of Ifng (encoding interferon (IFN)-gamma), Irf7 (encoding IFN regulator factor 7), and antiviral genes, such as Mx2 and Eif2ak2 (encoding PKR), were observed in IAV-infected p53KO mice, suggesting an impaired IFN-mediated immune response against IAV infection in the absence of p53. In addition, dysregulated expression levels of proinflammatory cytokines and chemokines, such as Ccl2 (encoding MCP-1), Cxcl9, Cxcl10 (encoding IP-10), and Tnf, were detected in IAV-infected p53KO mice during early IAV infection, reflecting an aberrant inflammatory response.ConclusionLack of p53 resulted in the impaired expression of genes involved in IFN signaling and the dysregulated expression of cytokine and chemokine genes in IAV-infected mice, suggesting an essential role of p53 in the regulation of antiviral and inflammatory responses during IAV infection.Electronic supplementary materialThe online version of this article (doi:10.1186/s12920-015-0127-8) contains supplementary material, which is available to authorized users.

Influenza A Virus (IAV) infection followed by bacterial pneumonia often leads to hospitalization and death in individuals from high risk groups. Following infection, IAV triggers the process of viral RNA replication which in turn disrupts healthy gut microbial community, while the gut microbiota plays an instrumental role in protecting the host by evolving colonization resistance. Although the underlying mechanisms of IAV infection have been unraveled, the underlying complex mechanisms evolved by gut microbiota in order to induce host immune response following IAV infection remain evasive. In this work, we developed a novel Maximal-Clique based Community Detection algorithm for Weighted undirected Networks (MCCD-WN) and compared its performance with other existing algorithms using three sets of benchmark networks. Moreover, we applied our algorithm to gut microbiome data derived from fecal samples of both healthy and IAV-infected pigs over a sequence of time-points. The results we obtained from the real-life IAV dataset unveil the role of the microbial families Ruminococcaceae, Lachnospiraceae, Spirochaetaceae and Prevotellaceae in the gut microbiome of the IAV-infected cohort. Furthermore, the additional integration of metaproteomic data enabled not only the identification of microbial biomarkers, but also the elucidation of their functional roles in protecting the host following IAV infection. Our network analysis reveals a fast recovery of the infected cohort after the second IAV infection and provides insights into crucial roles of Desulfovibrionaceae and Lactobacillaceae families in combating Influenza A Virus infection. Source code of the community detection algorithm can be downloaded from https://github.com/AniBhar84/MCCD-WN.

Here, we studied the IFN-regulated innate immune response against influenza A virus (IAV) infection in the mouse lung and the therapeutic effect of IFN-λ2/3 in acute IAV lung infection. For viral infections, IAV (WS/33, H1N1, PR8 H1N1, H5N1) were inoculated into wild-type mice by intranasal delivery, and IAV mRNA level and viral titer were measured. To compare the antiviral effect of IFNs in vivo in the lung, neutralizing antibodies and recombinant IFNs were used. After intranasal inoculation of IAV into mice, viral infection peaked at 7 days postinfection, and the IAV titer also reached its peak at this time. We found that IFN-β and IFN-λ2/3 were preferentially induced after IAV infection and the IFN-λ2/3-mediated innate immune response was specifically required for the induction of IFN-stimulated genes (ISGs) transcription in the mouse respiratory tract. Neutralization of secreted IFN-λ2/3 aggravated acute IAV lung infection in mice with intact IFN-β induction; consistent with this finding, the transcription of ISGs was significantly reduced. Intranasal administration of IFN-λ2/3 significantly suppressed various strains of IAV infection, including WS/33 (H1N1), PR (H1N1), and H5N1 in the mouse lung, and was accompanied by greater up-regulation of ISGs. Taken together, our data indicate that the IFN-λ2/3-mediated innate immune response is necessary to protect the lungs from IAV infection, and intranasally delivered IFN-λ2/3 has the potential to be a useful therapeutic strategy for treating acute IAV lung infection.