MDA5

Abstract: West Nile virus (WNV) is a member of the Flavivirus genus of the family Flaviviridae. This genus contains a number of arthropod-borne human pathogens, including dengue virus (DV), Japanese encephalitis virus, yellow fever virus, and tick-borne encephalitis virus (26). WNV was associated with fever and infrequent encephalitis cases in humans in Africa, the Middle East, and Europe from its discovery in 1938 through the 1990s. In 1999, WNV was first detected in New York City, and from there it rapidly spread across the United States, some regions of Canada, Mexico, and Central America. The majority of WNV infections are asymptomatic; however, a portion of infections result in West Nile fever, and a subset of infections lead to viral invasion of the central nervous system that results in encephalitis, paralysis, and meningitis, outcomes which are especially prevalent in immunocompromised and aged individuals (4). The mechanisms by which WNV causes disease are not completely understood, but studies with a hamster model of the disease suggest that following a brief peripheral replication cycle, the virus crosses the blood-brain barrier, where it infects neurons, causing cell death (47). The direct effect of WNV on neurons or an immune response to their infection may also be responsible for encephalitis and meningoencephalitis in humans (13). Pretreatment of animals with type I interferons (IFN-α/IFN-β) has been shown to block flavivirus disease (3, 23), and animals defective in the IFN response have been shown to be more susceptible to flavivirus infection (19, 28, 39). Although the precise IFN-stimulated genes (ISGs) that are responsible for preventing or controlling flavivirus infections are unknown, a number of studies have demonstrated that flavivirus-infected cells prevent IFN-induced phosphorylation of STAT molecules, which carry the signal from the ligated IFN receptor to the nucleus to activate the transcription of ISGs (1, 11, 20, 24, 25, 32, 37, 44). Interestingly, the precise mechanism by which flaviviruses alter STAT phosphorylation appears to differ among members of the genus (1, 24, 32). IFN is produced by most eukaryotic cells in response to viral infection and/or recognition of virus-associated macromolecules (known as pathogen-associated molecular patterns [PAMPs]), such as single- or double-stranded RNA (ssRNA and dsRNA, respectively). In many mammalian cell types, ligation of Toll-like receptor 3 (TLR3) to extracellular dsRNA or recognition of intracellular dsRNA by the intracellular helicase mda5 or RIG-I induces the phosphorylation and activation of the constitutively expressed IFN regulatory factor 3 (IRF3), leading to nuclear translocation and activation of transcription of the genes for IFN-β and IFN-α subtype 4 (14). Recent studies have indicated that in cell cultures, a subset of viruses appear to activate the mda5 pathway, whereas others, including the flavivirus Japanese encephalitis virus, activate the RIG-I pathway (21). In some cases, IFN-α expression has been linked to protein kinase R activation via binding of intracellular dsRNA (9). Furthermore, multiple IFN-α subtypes can also be induced by PAMP-stimulated signal transduction pathways that lead to the phosphorylation of IRF7, which can be triggered by binding of ssRNA to TLR7/8. Interestingly, IRF7 is constitutively expressed in only a subset of cells, but the IRF7 gene is an ISG, so following IFN binding, many cells can produce IRF7, permitting them to amplify the IFN signal if stimulated by ssRNA (12). For many infections, a subset of cells known as plasmacytoid dendritic cells (pDCs), which express IRF7 constitutively, have been implicated as key IFN producers (16). These cells can produce extremely high levels of IFN in response to stimulation with infectious disease agents or components thereof. Activated pDCs also produce other cytokines, notably interleukin-12 (IL-12), tumor necrosis factor alpha, granulocyte-macrophage colony-stimulating factor, and IL-3, and chemokines, such as CCL3, CCL4, CCL5, CCL22, CCL19, and CXCL13 (2, 5, 33). However, pDCs are not the only cell type that express IRF7 constitutively. Other lymphocytes, including monocytes, B cells, and dendritic cell precursors (pDC2) (18), also express IRF7 in the resting state and are hence able to induce synthesis of IFN-α through the IRF7 pathway (reviewed in reference 22). Virus-like particles (VLPs) have been used as tools to study RNA virus infection in vitro and in vivo. VLPs consist of subgenomic replicating genomes lacking structural protein genes (replicons) that have been encapsidated by the missing structural proteins provided in trans by packaging cells. VLPs are thus able to infect cells and initiate genome replication in a manner that mimics that of normal virus, but unlike infections with normal virus, VLP infections cannot spread in the absence of trans-expressed structural proteins. In the case of both alphaviruses (35) and flaviviruses (43), VLPs have been used to identify the first cells that are infected in insect vectors of these viruses. Furthermore, for the alphavirus Venezuelan equine encephalitis virus, VLPs have been used to identify the first cells that are infected in animal models (29), and recent studies with Venezuelan equine encephalitis virus VLPs have shown that these VLPs (referred to as VRPs in the previous study) can strongly stimulate antiviral responses (46). In the studies described in this paper, we used WNV VLPs to study the early events in WNV infection in mice, demonstrating that WNV VLPs induce a rapid IFN response, resulting in very high levels of IFN-α in the serum between 8 and 24 h after either intraperitoneal (i.p.) inoculation or subcutaneous inoculation in the footpad (f.p. inoculation). Since VLPs can undergo only a single round of infection, these studies have demonstrated that the very first cells infected in an animal are capable of stimulating the production of high levels of IFN. IFN production was dependent on the replicative capacity of VLPs, since mice inoculated with UV-inactivated VLPs did not produce IFN. Immunohistochemical (IHC) detection of WNV antigen-positive cells in the popliteal lymph nodes (pLN) after f.p. inoculation with VLPs and the demonstration of high levels of IFN mRNA in pLN collected from VLP-inoculated animals implicate this lymphoid organ as a prominent source of IFN production. Finally, the finding that IRF3−/− animals produced levels of IFN similar to those of wild-type animals suggests that neither the RIG-I/mda5 nor the TLR3 pathway, known to be important for IFN-β induction, is important for this early response to WNV infection.

Abstract: Summary Loss-of-function of ADAR1 causes the severe autoinflammatory disease Aicardi-Goutieres Syndrome (AGS). ADAR1 converts adenosines into inosines within double-stranded (ds) RNA. This process called A-to-I editing masks self-dsRNA from detection by the antiviral dsRNA sensor MDA5. ADAR1 binds to dsRNA in both the canonical A-form and in the poorly defined Z-conformation (Z-RNA). Mutations in the Z-RNA binding Zα-domain of ADAR1 are common in AGS patients. How loss of ADAR1/Z-RNA interaction contributes to disease development is unknown. Using ADAR1 Zα-domain mutant human cells and knock-in mice, we demonstrate that abrogated binding of ADAR1 to Z-RNA leads to reduced A-to-I editing of dsRNA structures formed by pairing of inversely oriented SINEs. As a result, ADAR1 Zα-domain mutant human cells and transgenic mice develop a spontaneous MDA5-dependent immune response. This shows that the interaction between ADAR1 and Z-RNA restricts sensing of self-dsRNA and prevents AGS development.

Abstract: RIG-I-Like Receptors (RLRs) RIG-I, MDA5, and LGP2, are vital pathogen recognition receptors in the defense against RNA viruses. West Nile Virus (WNV) infections continue to grow in the US. Here, we use a systems biology approach to define the contributions of each RLR in the innate immune response to WNV. Genome-wide RNAseq and bioinformatics analyses of macrophages from mice lacking either RLR reveal that the RLRs drive distinct immune gene activation and response polarization to mediate an M1/inflammatory signature while suppressing the M2/wound healing phenotype. While LGP2 functions to modulate inflammatory signaling, RIG-I and MDA5 together are essential for M1 macrophage polarization in vivo and the control of WNV infection through potential downstream control of ATF4 and SMAD4 to regulate target gene expression for cell polarization. These analyses reveal the RLR-driven signature of macrophage polarization, innate immune protection, and immune programming against WNV infection.