Double-stranded RNA (dsRNA) is produced during the replication cycle of most viruses and triggers antiviral immune responses through Toll-like receptor 3 (TLR3). However, the molecular mechanisms and subcellular compartments associated with dsRNA-TLR3-mediated signaling are largely unknown. Here we show that c-Src tyrosine kinase is activated by dsRNA in human monocyte-derived dendritic cells, and is recruited to TLR3 in a dsRNAdependent manner. DsRNA-induced activation of interferon-regulatory factor 3 and signal transducer and activator of transcription 1 was abolished in Src kinase-deficient cells, and restored by adding back c-Src, suggesting a central role of c-Src in antiviral immunity. We also provide evidence that TLR3 is localized in the endoplasmic reticulum of unstimulated cells, moves to dsRNA-containing endosomes in response to dsRNA, and colocalizes with c-Src on endosomes containing dsRNA in the lumen. These results provide novel insight into the molecular mechanisms of TLR3-mediated signaling, which may contribute to the understanding of innate immune responses during viral infections.
Positive-stranded RNA viruses, such as hepatitis C virus (HCV), assemble their viral replication complexes by remodeling host intracellular membranes to a membranous web. The precise composition of these replication complexes and the detailed mechanisms by which they are formed are incompletely understood. Here we show that the human immunity-related GTPase M (IRGM), known to contribute to autophagy, plays a previously unrecognized role in this process. We show that IRGM is localized at the Golgi apparatus and regulates the fragmentation of Golgi membranes in response to HCV infection, leading to colocalization of Golgi vesicles with replicating HCV. Our results show that IRGM controls phosphorylation of GBF1, a guanine nucleotide exchange factor for Arf-GTPases, which normally operates in Golgi membrane dynamics and vesicle coating in resting cells. We also find that HCV triggers IRGM-mediated phosphorylation of the early autophagy initiator ULK1, thereby providing mechanistic insight into the role of IRGM in HCV-mediated autophagy. Collectively, our results identify IRGM as a key Golgi-situated regulator that links intracellular membrane remodeling by autophagy and Golgi fragmentation with viral replication.HCV | Golgi fragmentation | autophagy | IRGM | membranous web H epatitis C virus (HCV) is a positive-sense RNA virus in the family Flaviviridae that is a major cause of chronic liver disease. All positive-strand RNA viruses studied until now, including HCV, replicate their genomes in association with cellular membrane rearrangements. In this process, viruses remodel intracellular membranes [e.g., of mitochondria, endoplasmic reticulum (ER), and plasma membrane] to generate membrane structures such as single-or double-membrane vesicles that contribute to viral replication complexes (VRCs). HCV replication takes place at a unique subcellular compartment, the membranous web (MW), which has been proposed to be derived from the ER (1, 2). The HCV MW has a complex morphology consisting of clusters of single-, double-, and multimembrane vesicles and probably includes autophagosomes and lipid droplets (1, 3, 4). Recent findings reveal that the MW is produced by distinct HCV nonstructural (NS) proteins acting through sequential interaction with several host factors, such as the virus-targeted phosphatidylinositol-4 kinase III α (PI4KIIIα) (2, 3), but the full spectrum of host components and precise membrane composition that supports HCV replication are not fully defined.Autophagy is an evolutionarily conserved cellular mechanism that involves intracellular membrane trafficking and degradation to maintain cell homeostasis. Viruses, including HCV, have been reported to exploit autophagy for replication purposes (4-6), but the mechanism by which this exploitation occurs is largely unknown. De novo synthesis of autophagosomes is a complex process that involves the formation of a phagophore membrane and its elongation. Initiation of autophagy is regulated by the mammalian target of rapamycin complex 1 (mTORC1), which neg...
Human metapneumovirus (hMPV) causes severe airway infection in children that may be caused by an unfavorable immune response. The nature of the innate immune response to hMPV in naturally occurring infections in children is largely undescribed, and it is unknown if inflammasome activation is implicated in disease pathogenesis. We examined nasopharynx aspirates and blood samples from hMPV-infected children without detectable co-infections. The expression of inflammatory and antiviral genes were measured in nasal airway secretions by relative mRNA quantification while blood plasma proteins were determined by a multiplex immunoassay. Several genes were significantly up-regulated at mRNA and protein level in the hMPV infected children. Most apparent was the expression of the chemokine IP-10, the pro-inflammatory cytokine IL-18 in addition to the interferon inducible gene ISG54. Interestingly, children experiencing more severe disease, as indicated by a severity index, had significantly more often up-regulation of the inflammasome-associated genes IL-1β and NLRP3. Overall, our data point to cytokines, particularly inflammasome-associated, that might be important in hMPV mediated lung disease and the antiviral response in children with severe infection. Our study is the first to demonstrate that inflammasome components are associated with increased illness severity in hMPV-infected children.
Generation and Functional In Vitro Analysis of Semliki Forest Virus Vectors Encoding TNF-α and IFN-γ
Cytokine gene delivery by viral vectors is a promising novel strategy for cancer immunotherapy. Semliki Forest virus (SFV) has many advantages as a delivery vector, including the ability to (i) induce p53-independent killing of tumor cells via apoptosis, (ii) elicit a type-I interferon (IFN) response, and (iii) express high levels of the transgene. SFV vectors encoding cytokines such as interleukin (IL)-12 have shown promising therapeutic responses in experimental tumor models. Here, we developed two new recombinant SFV vectors encoding either murine tumor necrosis factor-α (TNF-α) or murine interferon-γ (IFN-γ), two cytokines with documented immunostimulatory and antitumor activity. The SFV vector showed high infection rate and cytotoxicity in mouse and human lung carcinoma cells in vitro. By contrast, mouse and human macrophages were resistant to infection with SFV. The recombinant SFV vectors directly inhibited mouse lung carcinoma cell growth in vitro, while exploiting the cancer cells for production of SFV vector-encoded cytokines. The functionality of SFV vector-derived TNF-α was confirmed through successful induction of cell death in TNF-α-sensitive fibroblasts in a concentration-dependent manner. SFV vector-derived IFN-γ activated macrophages toward a tumoricidal phenotype leading to suppressed Lewis lung carcinoma cell growth in vitro in a concentration-dependent manner. The ability of SFV to provide functional cytokines and infect tumor cells but not macrophages suggests that SFV may be very useful for cancer immunotherapy employing tumor-infiltrating macrophages.
Identification of a Novel in Vivo Virus-targeted Phosphorylation Site in Interferon Regulatory Factor-3 (IRF3)
The transcription factor interferon regulatory factor-3 (IRF3) regulates expression of type I interferon- and plays an important role in antiviral immunity. Despite the biological importance of IRF3, its in vivo phosphorylation pattern has not been reported. In this study, we have identified residues in IRF3 that are phosphorylated in vivo after infection with Sendai virus. We found that Sendai virus induced phosphorylation of the C- Innate immune responses upon viral infections include production of antiviral cytokines and type I interferons (IFNs). 2The transcription factor interferon regulatory factor-3 (IRF3) is critical for IFN production and directs expression of several diverse genes that are implicated in the antiviral immune response (1). IRF3 is constitutively expressed in multiple tissues and shuttles between the cytoplasm and nucleus in resting cells. Activation of IRF3 involves its virus-induced phosphorylation at several sites in the C-terminal IRF3 dimerization and translocation to the nucleus. In the nucleus, IRF3 associates with cAMP-response element-binding protein-binding protein (CBP) or the closely related p300, promoting binding to promoters containing interferon-stimulated response elements to initiate transcription of target genes (2).Activation of IRF3 is initiated after recognition of viral nucleic acids by Toll-like receptors or by the cytoplasmic RNA helicases RIG-I and MDA5 (3, 4). These receptors recruit distinct adapter proteins to initiate signaling, which induce ubiquitination of the cytoplasmic adapter protein TRAF3, leading to activation of the IB kinase-related kinase TANK-binding kinase-1 (TBK1) and phosphorylation of IRF3 (5, 6). The activation mechanism of TBK1 is still poorly understood, but it involves phosphorylation of Ser 172 in the mitogen-activated protein kinase activation loop of TBK1 (7,8).From studies based on IRF3 mutagenesis, functional in vitro assays, and in vitro phosphorylations of IRF3 with TBK1 (9, 10), it has been proposed that IRF3 is regulated by phosphorylation of multiple residues that are clustered in its C terminus. The IRF3 residues that are phosphorylated in vivo upon viral infection have not been determined directly, but based on an antibody recognizing phosphorylated Ser 396 , this residue was suggested to be the main target of the IRF3-activating kinase TBK1 (11). It has been advocated that sequential phosphorylation of residues in site 1 ( (12)(13)(14)(15)(16). However, the sequential order of site 1 and site 2 phosphorylations has been debated. In a recent study, Panne et al. (9) examined IRF3 phosphorylated in vitro with TBK1 and proposed that phosphorylation of residues in site 2 alleviates autoinhibition and promotes site 1 phosphorylation and resultant IRF3 dimerization. However, proof for such a mechanism is still lacking, because the phosphorylation pattern of IRF3 in vivo after viral infection remains elusive. In recent years, mass spectrometry (MS)-based analysis has emerged as a major tool to identify specific post-translation...
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