Project description:The monomer-to-filament transition of MAVS is essential for the RIG-I/MDA5-mediated antiviral signaling. In quiescent cells, monomeric MAVS is under strict regulation for preventing its spontaneous aggregation, which would result in dysregulated interferon (IFN-?/?) production and autoimmune diseases like systemic lupus erythematosus. However, the detailed mechanism by which MAVS is kept from spontaneous aggregation remains largely unclear. Here, we show that upstream open reading frames (uORFs) within the MAVS transcripts exert a post-transcriptional regulation for preventing MAVS spontaneous aggregation and auto-activation. Mechanistically, we demonstrate that uORFs are cis-acting elements initiating leaky ribosome scanning of the downstream ORF codons, thereby repressing the full-length MAVS translation. We further uncover that endogenous MAVS generated from the uORF-deprived transcript spontaneously aggregates, triggering the Nix-mediated mitophagic clearance of damaged mitochondria and aggregated MAVS. Our findings reveal the uORF-mediated quantity and quality control of MAVS, which prevents aberrant protein aggregation and maintains innate immune homeostasis.

Project description:RIG-I-MAVS signaling pathway plays a crucial role in defending against pathogen infection and maintaining immune balance. Upon detecting viral RNA, RIG-I triggers the formation of prion-like aggregates of the adaptor protein MAVS, which then activates the innate antiviral immune response. However, the mechanisms that regulate the aggregation of MAVS are not yet fully understood. Here, we identified WDR77 as a MAVS-associated protein, which negatively regulates MAVS aggregation. WDR77 binds to MAVS proline-rich region through its WD2-WD3-WD4 domain and inhibits the formation of prion-like filament of recombinant MAVS in vitro. In response to virus infection, WDR77 is recruited to MAVS to prevent the formation of its prion-like aggregates and thus downregulate RIG-I-MAVS signaling in cells. WDR77 deficiency significantly potentiates the induction of antiviral genes upon negative-strand RNA virus infections, and myeloid-specific Wdr77-deficient mice are more resistant to RNA virus infection. Our findings reveal that WDR77 acts as a negative regulator of the RIG-I-MAVS signaling pathway by inhibiting the prion-like aggregation of MAVS to prevent harmful inflammation.

Project description:Innate immunity plays a pivotal role in virus infection. RIG-I senses viral RNA and initiates an effective innate immune response for type I interferon production. To transduce RIG-I-mediated antiviral signalling, a mitochondrial protein MAVS forms prion-like aggregates to activate downstream kinases and transcription factors. However, the activation mechanism of RIG-I is incompletely understood. Here we identify two ubiquitin enzymes Ube2D3 and Ube2N through chromatographic purification as activators for RIG-I on virus infection. We show that together with ubiquitin ligase Riplet, Ube2D3 promotes covalent conjugation of polyubiquitin chains to RIG-I, while Ube2N preferentially facilitates production of unanchored polyubiquitin chains. In the presence of these polyubiquitin chains, RIG-I induces MAVS aggregation directly on the mitochondria. Our data thus reveal two essential polyubiquitin-mediated mechanisms underlying the activation of RIG-I and MAVS for triggering innate immune signalling in response to viral infection in cells.

Project description:Cysteine palmitoylation or S-palmitoylation catalyzed by the ZDHHC family of acyltransferases regulates the biological function of numerous mammalian proteins as well as viral proteins. However, understanding of the role of S-palmitoylation in antiviral immunity against RNA viruses remains very limited. The adaptor protein MAVS forms functionally essential prion-like aggregates upon activation by viral RNA-sensing RIG-I-like receptors. Here, we identify that MAVS, a C-terminal tail-anchored mitochondrial outer membrane protein, is S-palmitoylated by ZDHHC7 at Cys508, a residue adjacent to the tail-anchor transmembrane helix. Using superresolution microscopy and other biochemical techniques, we found that the mitochondrial localization of MAVS at resting state mainly depends on its transmembrane tail-anchor, without regulation by Cys508 S-palmitoylation. However, upon viral infection, MAVS S-palmitoylation stabilizes its aggregation on the mitochondrial outer membrane and thus promotes subsequent propagation of antiviral signaling. We further show that inhibition of MAVS S-palmitoylation increases the host susceptibility to RNA virus infection, highlighting the importance of S-palmitoylation in the antiviral innate immunity. Also, our results indicate ZDHHC7 as a potential therapeutic target for MAVS-related autoimmune diseases.

Project description: Not available

Project description:The innate immune system recognizes nucleic acids during viral infection and stimulates cellular antiviral responses. Intracellular detection of RNA virus infection is mediated by the RNA helicases RIG-I (retinoic acid inducible gene I) and MDA-5, which recognize viral RNA and signal through the adaptor molecule MAVS (mitochondrial antiviral signaling) to stimulate the phosphorylation and activation of the transcription factors IRF3 (interferon regulatory factor 3) and IRF7. Once activated, IRF3 and IRF7 turn on the expression of type I interferons, such as beta interferon. Interestingly, unlike other signaling molecules identified in this pathway, MAVS contains a C-terminal transmembrane (TM) domain that is essential for both type I interferon induction and localization of MAVS to the mitochondrial outer membrane. However, the role the MAVS TM domain plays in signaling remains unclear. Here we report the identification of a function for the TM domain in mediating MAVS self-association. The activation of RIG-I/MDA-5 leads to the TM-dependent dimerization of the MAVS N-terminal caspase recruitment domain, thereby providing an interface for direct binding to and activation of the downstream effector TRAF3 (tumor necrosis factor receptor-associated factor 3). Our results reveal a role for MAVS self-association in antiviral innate immunity signaling and provide a molecular mechanism for downstream signal transduction.

Project description:Genetic variation is associated with diseases. As a type of genetic variation occurring with certain regularity and frequency, the single nucleotide polymorphism (SNP) is attracting more and more attention because of its great value for research and real-life application. Mitochondrial antiviral signalling protein (MAVS) acts as a common adaptor molecule for retinoic acid-inducible gene-I (RIG-I)-like receptors (RLRs), which can recognize foreign RNA, including viral RNA, leading to the induction of type I interferons (IFNs). Therefore, MAVS is thought to be a crucial molecule in antiviral innate immunity. We speculated that genetic variation of MAVS may result in susceptibility to infectious diseases. To assess the risk of viral infection based on MAVS variation, we tested the effects of twelve non-synonymous MAVS coding-region SNPs from the National Center for Biotechnology Information (NCBI) database that result in amino acid substitutions. We found that five of these SNPs exhibited functional alterations. Additionally, four resulted in an inhibitory immune response, and one had the opposite effect. In total, 1,032 human genomic samples obtained from a mass examination were genotyped at these five SNPs. However, no homozygous or heterozygous variation was detected. We hypothesized that these five SNPs are not present in the Japanese population and that such MAVS variations may result in serious immune diseases.

Project description:In response to virus infection, RIG-I senses viral RNA and activates the adaptor protein MAVS, which then forms prion-like filaments and stimulates a specific signalling pathway leading to type I interferon production to restrict virus proliferation. However, the mechanisms by which MAVS activity is regulated remain elusive. Here we identify distinct regions of MAVS responsible for activation of transcription factors interferon regulatory factor 3 (IRF3) and nuclear factor kappa-light-chain-enhancer of activated B cells (NF-?B). These IRF3- and NF-?B-stimulating regions recruit preferential TNF receptor-associated factors (TRAFs) for downstream signalling. Strikingly, these regions' activities are inhibited by their respective adjacent regions in quiescent MAVS. Our data thus show that an autoinhibitory mechanism modulates MAVS activity in unstimulated cells and, on viral infection, individual regions of MAVS are released following MAVS filament formation to activate antiviral signalling cascades.

Project description:Bacterial and viral mRNAs are often polycistronic. Akin to alternative splicing, alternative translation of polycistronic messages is a mechanism to generate protein diversity and regulate gene function. Although a few examples exist, the use of polycistronic messages in mammalian cells is not widely appreciated. Here we report an example of alternative translation as a means of regulating innate immune signaling. MAVS, a regulator of antiviral innate immunity, is expressed from a bicistronic mRNA encoding a second protein, miniMAVS. This truncated variant interferes with interferon production induced by full-length MAVS, whereas both proteins positively regulate cell death. To identify other polycistronic messages, we carried out genome-wide ribosomal profiling and identified a class of antiviral truncated variants. This study therefore reveals the existence of a functionally important bicistronic antiviral mRNA and suggests a widespread role for polycistronic mRNAs in the innate immune system.

Project description:Innate immunity serves as the primary defense against viral and microbial infections in humans. Among its components, retinoic acid-inducible gene I (RIG-I)-like receptors (RLRs) are well-characterized intracellular pattern-recognition proteins that trigger innate immune responses upon viral infection. However, the precise influence of cellular metabolites, especially fatty acids, on the regulation of RLR-mediated antiviral innate immunity remains largely elusive. Here, through screening a metabolite library, palmitic acid (PA) has been identified as a crucial metabolite responsible for modulating antiviral infections. Mechanistically, PA induces the palmitoylation of MAVS, leading to MAVS aggregation and subsequent activation, thereby enhancing the innate immune response against viral infections. Functionally, the enzyme palmitoyl-transferase ZDHHC24 plays a key role in catalyzing the palmitoylation of MAVS at both C46 and C79 residues, thereby facilitating the transduction of RLR-mediated TBK1-IRF3-IFN signaling pathway, particularly under conditions of PA stimulation or high-fat diet feeding. Conversely, the absence of ZDHHC24 significantly attenuates virus-induced innate immune responses in both cells and mice. Moreover, APT2 counteracts with ZDHHC24 to de-palmitoylate MAVS, thus inhibiting the antiviral response. Consequently, inhibition of APT2 using compounds like ML349 effectively reverses MAVS palmitoylation and activation in response to antiviral infections. These findings underscore the critical role of PA and ZDHHC24 in regulating antiviral innate immunity through MAVS palmitoylation, and suggest potential therapeutic strategies for combating viral infections, such as enhancing PA intake or specifically targeting APT2.