Project description:Human Respiratory Syncytial Virus (hRSV) is a prevalent pathogen posing significant risks to infants and older adults. While the roles of RSV non-structural proteins NS1 protein in modulating host immune responses remains poorly defined, its potential impact on viral pathogenicity is critical. We employed CUT&RUN of NS1, Mediator, and ATF3 in WT NS1 and mutant NS1 expressing A549 cells and bulk RNA sequencing of WT and mutant NS1-expressing A549 (GSE155151) and RSV infection in human lung air-liquid interface (ALI) cultures to elucidate the perterbations of transcriptional regulatory control induced by NS1. Coupled with our earlier work, these epigenomic and transcriptomic profiling datasets provides deeper insights into the molecular mechanisms through which RSV NS1 protein disrupts host immune functions.

Project description:Human respiratory syncytial virus (RSV) is the leading cause of severe acute lower respiratory tract infections in infants worldwide. Non-structural protein NS1 of RSV modulates the host innate immune response by acting as an antagonist of type I and type III interferon (IFN) production and signaling in multiple ways. It is likely that NS1 performs this function by interacting with different host proteins. In order to obtain a comprehensive overview of NS1 interaction partners, we performed three complementary protein-protein interaction screens i.e. BioID, MAPPIT and KISS. The BioID proximity screen was performed during an RSV infection in A549 cells. MED25, a subunit of the Mediator complex, was identified in all 3 performed screening methods as a potential NS1 interacting protein. We confirmed the interaction between MED25 and RSV NS1 by co-immunoprecipitation, not only upon overexpression of NS1, but also with endogenous NS1 during RSV infection. We also demonstrate that the replication of RSV is enhanced in MED25 knockout A549 cells, suggesting a potential antiviral role of MED25 during RSV infection. Mediator subunits function as transcriptional coactivators and are involved in transcriptional regulation of their target genes. Therefore, the interaction between RSV NS1 and cellular MED25 might be beneficial during an RSV infection as this can affect host transcription and the host immune response to infection.

Project description:Human respiratory syncytial virus (RSV) is a common cause of lower respiratory tract infections in young children, the elderly, and immunocompromised individuals. Prior exposure to RSV affords little protection and many are susceptible to reinfection throughout life. Virally encoded non-structural (NS) protein 1 (NS1) is thought to modulate host responses in the cytosol. Here, we describe the nuclear localization of NS1 during RSV infection and a corresponding nuclear role in modulating host transcription. In support, we show that a significant proportion of NS1 is partitions to the nucleus and that NS1 alone is necessary and sufficient to translocate into the nucleus. NS1 co-localizes with exportin XPO1 and inhibition of XPO1 results in NS1 accumulation in the nucleus. Furthermore, nuclear NS1 is chromatin-associated and co-immunoprecipitates with Mediator complex proteins. Chromatin-immunoprecipitation demonstrates enrichment of NS1 binding overlapping Mediator and interferon-stimulated transcription factor binding sites that lie within regulatory elements of genes differentially expressed during RSV infection. Mutation of the unique alpha helix in NS1 enhances its repressive effect on host gene expression. Together, these data suggest that nuclear NS1 may alter host responses to RSV infection by binding at the promoters and enhancers of host immune response genes and disrupting host transcriptional regulators. Our study identifies yet another regulatory layer of interactions with RSV proteins that shapes host response to RSV and potentially impacts long-term immunity to RSV.

Project description:Human respiratory syncytial virus (RSV) is a common cause of lower respiratory tract infections in young children, the elderly, and immunocompromised individuals. Prior exposure to RSV affords little protection and many are susceptible to reinfection throughout life. Virally encoded non-structural (NS) protein 1 (NS1) is thought to modulate host responses in the cytosol. Here, we describe the nuclear localization of NS1 during RSV infection and a corresponding nuclear role in modulating host transcription. In support, we show that a significant proportion of NS1 is partitions to the nucleus and that NS1 alone is necessary and sufficient to translocate into the nucleus. NS1 co-localizes with exportin XPO1 and inhibition of XPO1 results in NS1 accumulation in the nucleus. Furthermore, nuclear NS1 is chromatin-associated and co-immunoprecipitates with Mediator complex proteins. Chromatin-immunoprecipitation demonstrates enrichment of NS1 binding overlapping Mediator and interferon-stimulated transcription factor binding sites that lie within regulatory elements of genes differentially expressed during RSV infection. Mutation of the unique alpha helix in NS1 enhances its repressive effect on host gene expression. Together, these data suggest that nuclear NS1 may alter host responses to RSV infection by binding at the promoters and enhancers of host immune response genes and disrupting host transcriptional regulators. Our study identifies yet another regulatory layer of interactions with RSV proteins that shapes host response to RSV and potentially impacts long-term immunity to RSV.

Project description:Gene transcription effects of mutations in the infuenza virus A/Hong Kong/1/1968(H3N2) nonstructural 1 NS1 gene in infected human A549 (lung epithilium) cells Influenza A/Hong Kong/156/1997(H5N1) virus NS1 gene mutations F103L and M106I both increase IFN antagonism, virulence and cytoplasmic localization but differ in binding to RIG-I and CPSF30 (manuscript submitted to Virology Journal). Human cells were infected with influenza viruses mutants with specific gain of function mutations in the NS1 gene in order to assess the affects of each mutation on host gene expression. Human (A549) and mouse (M1) cells were infected at a multiplicity of infection of 2 (infectious viruses/cell) and incubated for 8 hr before collection of total RNA and microarray anlaysis using the Affymetrix platforms. Samples were compared in triplicate to mock PBS infected (uninfected) cells to detecte dysregulated genes for A/HK/1/1968(H3N2) wt, and the following NS1 gene mutants: F103L, M106I, M106V, and F103L + M106I. Background: The genetic basis for avian to mammalian host switching in influenza A virus is largely unknown. The human A/HK/156/1997(H5N1) virus that transmitted from poultry possesses NS1 gene mutations F103L + M106I that are virulence determinants in the mouse model of pneumonia; however their individual roles have not been determined. The emergent A/Shanghai/1/2013(H7N9)-like viruses also possess these mutations which may contribute to their virulence and ability to switch species. Methods: NS1 mutant viruses were constructed by reverse genetics and site directed mutagenesis on human and mouse-adapted backbones. Mouse infections assessed virulence, virus yield, tissue infection, and IFN induction. NS1 protein proprieties were assessed for subcellular distribution, IFN antagonism (mouse and human), CPSF30 and RIG-I domain binding, effect on host gene transcription (microarray); and the natural prevalence of 103L and 106I mutants was assessed. Results: Each of the F103L and M106I mutations contributes additively to virulence to reduce the lethal dose by >800 and >3,200 fold respectively by mediating alveolar tissue infection with >100 fold increased infectious yields. The 106I NS1 mutant lost CPSF binding but the 103L mutant maintained binding that correlated with an increased general decrease in host gene expression in human but not mouse cells. Each mutation positively modulated the inhibition of IFN induction in mouse cells and activation of the IFN-M-NM-2 promoter in human cells but not in combination in human cells indicating negative epistasis. Each of the F103L and M106I mutations restored a defect in cytoplasmic localization of H5N1 NS1 in mouse cells. Human H1N1 and H3N2 NS1 proteins bound to the CARD, helicase and RD RIG-I domains, whereas the H5N1 NS1 with the same consensus 103F and 106M mutations did not bind these domains, which was partially or totally restored by the F103L or M106I mutations respectively. Conclusions: The F103L and M106I mutations in the H5N1 NS1 protein each increased IFN antagonism and mediated interstitial pneumonia in mice that was associated with increased cytoplasmic localization and altered host factor binding. These mutations may contribute to the ability of previous HPAI H5N1 and recent LPAI H7N9 viruses to switch hosts and cause severe disease in mammals. Triplicate biological replicates of mock PBS treated (uninfected) cells to detecte dysregulated genes for A/HK/1/1968(H3N2) wt, and the following NS1 gene mutants: F103L, M106I, M106V, and F103L + M106I. Cells were infected at a multiplicty of infection of 2 and cells were incubated for 8 hr at 37 C for 8 hrs before RNA extraction and analysis of 3 biological replicates relative to mock PBS infected cells.

Project description:Influenza A virus (IAV) is an important human respiratory pathogen that causes significant seasonal epidemics and potential devastating pandemics. As part of its life cycle, IAV encodes the multifunctional protein NS1, that, among many roles, prevents immune detection and limits interferon (IFN) production. As different host immune pathways exert different selective pressures against IAV as replication progresses, we expect a prioritization in the host immune antagonism by NS1. In this work, we profiled bulk transcriptomic differences in a primary bronchial epithelial cell model facing IAV infections at distinct NS1 levels. We further demonstrated that the intracellular NS1 levels in-part shapes the host response heterogeneity at single cell level. We found that modulation of NS1 levels reveal a ranking in its inhibitory roles: modest NS1 expression is sufficient to inhibit immune detection, and thus the expression of pro-inflammatory cytokines (including IFNs), but higher levels are required to inhibit IFN signaling and ISG expression. Lastly, inhibition of chaperones related to the unfolded protein response requires the highest amount of NS1, often associated with later stages of viral replication. This work demystifies some of the multiple functions ascribed to IAV NS1, highlighting the prioritization of NS1 in antagonizing the different pathways involved in the host response to IAV infection.

Project description:Gene transcription effects of mutations in the infuenza virus A/Hong Kong/1/1968(H3N2) nonstructural 1 NS1 gene in infected human A549 (lung epithilium) cells Influenza A/Hong Kong/156/1997(H5N1) virus NS1 gene mutations F103L and M106I both increase IFN antagonism, virulence and cytoplasmic localization but differ in binding to RIG-I and CPSF30 (manuscript submitted to Virology Journal). Human cells were infected with influenza viruses mutants with specific gain of function mutations in the NS1 gene in order to assess the affects of each mutation on host gene expression. Human (A549) and mouse (M1) cells were infected at a multiplicity of infection of 2 (infectious viruses/cell) and incubated for 8 hr before collection of total RNA and microarray anlaysis using the Affymetrix platforms. Samples were compared in triplicate to mock PBS infected (uninfected) cells to detecte dysregulated genes for A/HK/1/1968(H3N2) wt, and the following NS1 gene mutants: F103L, M106I, M106V, and F103L + M106I. Background: The genetic basis for avian to mammalian host switching in influenza A virus is largely unknown. The human A/HK/156/1997(H5N1) virus that transmitted from poultry possesses NS1 gene mutations F103L + M106I that are virulence determinants in the mouse model of pneumonia; however their individual roles have not been determined. The emergent A/Shanghai/1/2013(H7N9)-like viruses also possess these mutations which may contribute to their virulence and ability to switch species. Methods: NS1 mutant viruses were constructed by reverse genetics and site directed mutagenesis on human and mouse-adapted backbones. Mouse infections assessed virulence, virus yield, tissue infection, and IFN induction. NS1 protein proprieties were assessed for subcellular distribution, IFN antagonism (mouse and human), CPSF30 and RIG-I domain binding, effect on host gene transcription (microarray); and the natural prevalence of 103L and 106I mutants was assessed. Results: Each of the F103L and M106I mutations contributes additively to virulence to reduce the lethal dose by >800 and >3,200 fold respectively by mediating alveolar tissue infection with >100 fold increased infectious yields. The 106I NS1 mutant lost CPSF binding but the 103L mutant maintained binding that correlated with an increased general decrease in host gene expression in human but not mouse cells. Each mutation positively modulated the inhibition of IFN induction in mouse cells and activation of the IFN-β promoter in human cells but not in combination in human cells indicating negative epistasis. Each of the F103L and M106I mutations restored a defect in cytoplasmic localization of H5N1 NS1 in mouse cells. Human H1N1 and H3N2 NS1 proteins bound to the CARD, helicase and RD RIG-I domains, whereas the H5N1 NS1 with the same consensus 103F and 106M mutations did not bind these domains, which was partially or totally restored by the F103L or M106I mutations respectively. Conclusions: The F103L and M106I mutations in the H5N1 NS1 protein each increased IFN antagonism and mediated interstitial pneumonia in mice that was associated with increased cytoplasmic localization and altered host factor binding. These mutations may contribute to the ability of previous HPAI H5N1 and recent LPAI H7N9 viruses to switch hosts and cause severe disease in mammals.

Project description:Human respiratory syncytial virus (hRSV) is a major cause of morbidity and mortality in the pediatric, elderly, and immune compromised populations. A gap in our understanding of hRSVdisease pathology is the interplay between virally encoded immune antagonists and host components that limit hRSV replication. hRSV encodes for non-structural (NS) proteins that are important immune antagonists; however, the role of these proteins in viral pathogenesis is incompletely understood. Here we report the crystal structure of hRSV NS1 protein, which suggests that NS1 is a structural paralog of hRSV matrix (M) protein. Comparative analysis of the shared structural fold with M revealed regions unique to NS1. Studies on NS1 WT or mutant alone or in recombinant RSVs demonstrate that structural regions unique to NS1 contribute to modulation of host responses, including inhibition of type I IFN responses, suppression of dendritic cell maturation, and promotion of inflammatory responses. Transcriptional profiles of A549 cells infected with recombinant RSVs show significant differences in multiple host pathways, suggesting that NS1 may have a greater role in regulating host responses than previously appreciated. These results provide a framework to target NS1 for therapeutic development to limit hRSV associated morbidity and mortality.

Project description:Dengue virus (DENV) is a major human pathogen that belongs to the flavivirus genus. Among non-structural viral proteins, NS1 is an enigmatic factor that is exclusively encoded by members of the flavivirus genus within the Flaviviridae family and accomplishes different functions during DENV infection. To gain insight into the molecular and cellular function of NS1 in viral replication, we generated a tagged NS1 DENV replicon and identified the associated host proteins during active viral replication. Replicons are self-replicating flavivirus RNAs containing large in-frame deletions in the structural genes and are useful tools to study translation and RNA amplification of several flaviviruses. To establish a global map of NS1-host protein interactions occurring during DENV replication, we stably expressed a DENV2 replicon encoding NS1 tagged with N-terminal FLAG and HA epitopes (FH-NS1) or the untagged version (WT) in three different human cell lines (Raji, HeLa and HAP1). Interactors of NS1 were identified by AP-MS/MS from these three different cell lines.

Project description:N6-methyladenosine (m6A) is the most prevalent internal modification of mRNAs in most eukaryotes. Likewise, viral RNAs may acquire m6A methylation during replication within these cells. Here we show that RNAs of human respiratory syncytial virus (RSV), a medically important non-segmented negative-sense (NNS) RNA virus, are modified by m6A within discreet regions and that these modifications enhance viral replication and pathogenesis. Overexpression of m6A binding proteins significantly enhanced RSV replication and gene expression. Knockdown of m6A methyltransferases decreased viral replication and gene expression whereas knockdown of m6A demethylases had the opposite effect. The G gene contained the most abundant m6A modifications. Recombinant RSV expressing a G gene lacking different m6A sites, resulted in RSVs with various degrees of defects in replication in A549 cells, primary well differentiated human airway epithelial (HAE) cultures, upper and lower respiratory tract of cotton rats, and were also less pathogenic to the lungs of cotton rats. One of the m6A-deficient rgRSVs, rgRSV-G12, was completely attenuated yet retained high immunogenicity in cotton rats. Moreover, a small molecule that inhibits S-adenosyl-L-homocysteine (SAH) hydrolase, thereby reducing the cellular SAH pool and viral RNA m6A, also inhibited RSV replication in HAE cells. Collectively, our results demonstrate viral m6A methylation upregulates RSV replication and pathogenesis and identify viral m6A methylation as a target for rational design of live attenuated vaccine candidates and for novel antiviral therapeutic agents for RSV.