Project description:Cells infected by influenza virus mount a large-scale antiviral response and most cells ultimately initiate cell-death pathways in an attempt to suppress viral replication. We performed a CRISPR/Cas9-knockout selection designed to identify host factors required for replication following viral entry. We identified a large class of presumptive antiviral factors that unexpectedly act as important pro-viral enhancers during influenza virus infection. One of these, IFIT2, is an interferon-stimulated gene with well-established antiviral activity but limited mechanistic understanding. As opposed to suppressing infection, we show here that IFIT2 is instead repurposed by influenza virus to promote viral gene expression. CLIP‐seq demonstrated that IFIT2 binds directly to viral and cellular mRNAs in AU‐rich regions, with bound cellular transcripts enriched in interferon‐stimulated mRNAs. Polysome and ribosome profiling revealed that IFIT2 prevents ribosome pausing on bound mRNAs. Together, the data link IFIT2 binding to enhanced translational efficiency for viral and cellular mRNAs and ultimately viral replication. Our findings establish a model for the normal function of IFIT2 as a protein that increases translation of cellular mRNAs to support antiviral responses and explain how influenza virus uses this same activity to redirect a classically antiviral protein into a pro-viral effector.

Project description:Short 5’ UTRs serve as a marker for mRNA translation inhibition by the IFIT2-IFIT3 antiviral complex

Project description:As early as 24 hours after RNA virus infection, up to 25% of all RNA molecules present in host cells are pathogenic viral RNA (vRNA), i.e. viral messenger RNA (vmRNA), viral genomic RNA (vgRNA), and double stranded replication intermediates (dsRNA). To prevent such a takeover of the host metabolism, the innate immune system of the infected organism must detect threat as soon as possible. When considering RNA viruses recognition, activation of timely proper immune response capable of sensing and neutralizing viral genetic material is crucial for cell survival. Viral nucleic acids are one of the strongest pathogen-associated molecular patterns (PAMPs), molecules causing particular immune system reactions. Human cells are armed with a variety of pattern recognition receptors (PRRs) responsible for PAMPs recognition. The main factors responsible for detecting foreign nucleic acids in mammalian cells have already been identified. For activation of any RNA sensor, detecting an abnormal molecular RNA pattern, not present under normal conditions, is obligatory. These patterns may be some chemical modification of RNA, or the absence of such one, specific secondary or tertiary RNA structure, particular sequence, or dsRNA that can derive from viral genome as it is in the case of dsRNA viruses or from annealed complementary RNA strands, which are generated as RNA virus replication intermediates. However, yet there is still very limited understanding of how different epitranscriptomic marks modulate host immune response. Therefore, we will attempt to comprehensively understand how chemical modifications of viral RNA influence its immunogenic potential and stability in infected cells. Moreover, we will study how epitranscriptomic marks deposited on viral RNAs shield transcripts from being recognized by host antiviral factors.

Project description:The cell intrinsic antiviral response of multicellular organisms developed over millions of years and critically relies on the ability to sense and eliminate viral nucleic acids. Here we used an affinity proteomics approach in evolutionary distant species (human, mouse and fly) to identify proteins that are conserved in their ability to associate with diverse viral nucleic acids. This approach revealed a conserved core of proteins targeting viral genetic material and species-specific interactants. Functional characterization of the influence of 181 candidates on replication of 6 distinct viruses in human cells and flies identified 128 nucleic acid binding proteins with an impact on virus growth. We identified the family of TAO kinases (TAOK1, -2 and -3) as dsRNA-interacting antiviral proteins and show their requirement in type-I interferon induction. Depletion of TAO kinases in mammals or flies led to an impaired response to virus infection characterized by a reduced induction of interferon stimulated genes in mammals and impaired expression of srg1 and diedel in flies. Overall, our study reveals a by far larger interaction space between viral genetic material and host factors than anticipated so far, attesting to the ancestral roots of innate immunity and to the lineage-specific pressures exerted by viruses.

Project description:The cell intrinsic antiviral response of multicellular organisms developed over millions of years and critically relies on the ability to sense and eliminate viral nucleic acids. Here we used an affinity proteomics approach in evolutionary distant species (human, mouse and fly) to identify proteins that are conserved in their ability to associate with diverse viral nucleic acids. This approach revealed a conserved core of proteins targeting viral genetic material and species-specific interactants. Functional characterization of the influence of 181 candidates on replication of 6 distinct viruses in human cells and flies identified 128 nucleic acid binding proteins with an impact on virus growth. We identified the family of TAO kinases (TAOK1, -2 and -3) as dsRNA-interacting antiviral proteins and show their requirement in type-I interferon induction. Depletion of TAO kinases in mammals or flies led to an impaired response to virus infection characterized by a reduced induction of interferon stimulated genes in mammals and impaired expression of srg1 and diedel in flies. Overall, our study reveals a by far larger interaction space between viral genetic material and host factors than anticipated so far, attesting to the ancestral roots of innate immunity and to the lineage-specific pressures exerted by viruses.

Project description:The cell intrinsic antiviral response of multicellular organisms developed over millions of years and critically relies on the ability to sense and eliminate viral nucleic acids. Here we used an affinity proteomics approach in evolutionary distant species (human, mouse and fly) to identify proteins that are conserved in their ability to associate with diverse viral nucleic acids. This approach revealed a conserved core of proteins targeting viral genetic material and species-specific interactants. Functional characterization of the influence of 181 candidates on replication of 6 distinct viruses in human cells and flies identified 128 nucleic acid binding proteins with an impact on virus growth. We identified the family of TAO kinases (TAOK1, -2 and -3) as dsRNA-interacting antiviral proteins and show their requirement in type-I interferon induction. Depletion of TAO kinases in mammals or flies led to an impaired response to virus infection characterized by a reduced induction of interferon stimulated genes in mammals and impaired expression of srg1 and diedel in flies. Overall, our study reveals a by far larger interaction space between viral genetic material and host factors than anticipated so far, attesting to the ancestral roots of innate immunity and to the lineage-specific pressures exerted by viruses.

Project description:Influenza virus repurposes the antiviral protein IFIT2 to promote translation of viral mRNAs

Project description:Appropriate cellular recognition of viruses is essential for the generation of effective innate and adaptive antiviral immunity. Viral sensors and their signalling components thus provide a crucial first line of host defence. Many exhibit subcellular relocalisation upon activation, triggering expression of interferon and antiviral genes. To identify novel signalling factors we analysed protein relocalisation on a global scale during viral infection. CREB Regulated Transcription Coactivators-2 and 3 (CRTC2/3) exhibited early cytoplasmic-to-nuclear translocation upon a diversity of viral stimuli, in diverse cell types. This movement was depended on Mitochondrial Antiviral Signalling Protein (MAVS), cyclo-oxygenase proteins and protein kinase A. We identify a key effect of transcription stimulated by CRTC2/3 translocation as production of the pro-fibrogenic cytokine interleukin-11. This may be important clinically in viral infections associated with fibrosis, including SARS-CoV-2.

Project description:In mammals, early resistance to viruses relies on interferons, which protect differentiated but not stem cells from viral replication. Many other organisms rely instead on RNA interference (RNAi) mediated by a specialised Dicer protein that cleaves viral double stranded RNA. Whether RNAi also contributes to mammalian antiviral immunity remains controversial. Here we identify an isoform of Dicer, named antiviral Dicer (aviD), that protects tissue stem cells from RNA viruses, including Zika virus and SARS-CoV-2, by dicing viral double-stranded RNA to orchestrate antiviral RNAi. Our work sheds light on the molecular regulation of antiviral RNAi in mammalian innate immunity in which different cell-intrinsic antiviral pathways are tailored to the differentiation status of cells.

Project description:In Drosophila, the siRNA pathway is initiated when exogenous or endogenous double stranded RNA (dsRNA) is processed into siRNAs by Dicer-2 (Dcr-2) and a dsRNA-binding protein (dsRBP) cofactor called Loquacious (Loqs). The siRNAs are then loaded onto Argonaute-2 (Ago2) protein by the action of Dcr-2 with another dsRBP cofactor called R2D2. Loaded Ago2 executes the destruction of target RNAs that have sequence complementarity to the siRNA. Dcr-2, R2D2, and Ago2 have also been shown to be required for innate antiviral defense in Drosophila. However, the biogenesis of virus-derived siRNAs (vsiRNAs) and their targets in virus-infected cells remain unclear. Here, we analyzed the antiviral response in Drosophila by monitoring the replication of different RNA viruses and deep sequencing of small RNAs in infected animals. We show that vsiRNAs are generated by Dcr-2 processing of dsRNA formed during viral genome replication and transcription. These vsiRNAs then directly target viral transcripts but not genomes, to inhibit viral replication. The biogenesis of vsiRNAs was virtually independent of Loqs and R2D2. R2D2, however, was essential for sorting and loading of vsiRNAs onto Ago2 and effective silencing of viral RNA expression. Loqs was completely dispensable for silencing of viruses in contrast to its role in silencing of endogenous targets. Our results suggest the existence of a specific siRNA pathway triggered by viral infection independent of conserved dsRBP cofactors and separate from the endogenous pathway. Inhibition of virus replication resulting from direct injection of viral RNA into Drosophila embryos was also not dependent on Loqs, suggesting the distinction of the two pathways is not related to the mode of entry but recognition of intrinsic features of viral RNA or its mode of replication. We speculate that this unique framework might be necessary for a prompt and efficient antiviral response We analyzed the small RNA reponse to viral infection by deep sequencing of small RNA libraries from wild type and RNAi mutant adult flies infected with Sindbis birus and Vesicular Stomatatis virus.