ERIS, an endoplasmic reticulum IFN stimulator, activates innate immune signaling through dimerization. Proc Natl Acad Sci U S A. 2009;106:8653-8658. [PMID: 19433799 DOI: 10.1073/pnas.0900850106]

Regulation of innate immune responses by autophagy-related proteins

Pattern recognition receptors detect microbial components and induce innate immune responses, the first line of host defense against infectious agents. However, aberrant activation of immune responses often causes massive inflammation, leading to the development of autoimmune diseases. Therefore, both activation and inactivation of innate immune responses must be strictly controlled. Recent studies have shown that the cellular machinery associated with protein degradation, such as autophagy, is important for the regulation of innate immunity. These studies reveal that autophagy-related proteins are involved in the innate immune response and may contribute to the development of inflammatory disorders.

Induction of type I interferons by bacteria

Type I interferons (IFNs) are secreted cytokines that orchestrate diverse immune responses to infection. Although typically considered to be most important in the response to viruses, type I IFNs are also induced by most, if not all, bacterial pathogens. Although diverse mechanisms have been described, bacterial induction of type I IFNs occurs upon stimulation of two main pathways: (i) Toll-like receptor (TLR) recognition of bacterial molecules such as lipopolysaccharide (LPS); (ii) TLR-independent recognition of molecules delivered to the host cell cytosol. Cytosolic responses can be activated by two general mechanisms. First, viable bacteria can secrete stimulatory ligands into the cytosol via specialized bacterial secretion systems. Second, ligands can be released from bacteria that lyse or are degraded. The bacterial ligands that induce the cytosolic pathways remain uncertain in many cases, but appear to include various nucleic acids. In this review, we discuss recent advances in our understanding of how bacteria induce type I interferons and the roles type I IFNs play in host immunity.

Autophagy and innate immunity: triggering, targeting and tuning

Autophagy is a conserved catabolic stress response pathway that is increasingly recognized as an important component of both innate and acquired immunity to pathogens. The activation of autophagy during infection not only provides cell-autonomous protection through lysosomal degradation of invading pathogens (xenophagy), but also regulates signaling by other innate immune pathways. This review will focus on recent advances in our understanding of three major areas of the interrelationship between autophagy and innate immunity, including how autophagy is triggered during infection, how invading pathogens are targeted to autophagosomes, and how the autophagy pathway participates in "tuning" the innate immune response.

Pattern recognition receptors and inflammation

Infection of cells by microorganisms activates the inflammatory response. The initial sensing of infection is mediated by innate pattern recognition receptors (PRRs), which include Toll-like receptors, RIG-I-like receptors, NOD-like receptors, and C-type lectin receptors. The intracellular signaling cascades triggered by these PRRs lead to transcriptional expression of inflammatory mediators that coordinate the elimination of pathogens and infected cells. However, aberrant activation of this system leads to immunodeficiency, septic shock, or induction of autoimmunity. In this Review, we discuss the role of PRRs, their signaling pathways, and how they control inflammatory responses.

TAX1BP1 and A20 inhibit antiviral signaling by targeting TBK1-IKKi kinases

Induction of type I interferons by the transcription factor IRF3 is essential in the initiation of antiviral innate immunity. Activation of IRF3 requires C-terminal phosphorylation by the upstream kinases TBK1-IKKi, where IRF3 phosphorylation promotes dimerization, and subsequent nuclear translocation to the IFNbeta promoter. Recent studies have described the ubiquitin-editing enzyme A20 as a negative regulator of IRF3 signaling by associating with TBK1-IKKi; however, the regulatory mechanism of A20 inhibition remains unclear. Here we describe the adaptor protein, TAX1BP1, as a key regulator of A20 function in terminating signaling to IRF3. Murine embryonic fibroblasts (MEFs) deficient in TAX1BP1 displayed increased amounts of IFNbeta production upon viral challenge compared with WT MEFs. TAX1BP1 inhibited virus-mediated activation of IRF3 at the level of TBK1-IKKi. TAX1BP1 and A20 blocked antiviral signaling by disrupting Lys(63)-linked polyubiquitination of TBK1-IKKi independently of the A20 deubiquitination domain. Furthermore, TAX1BP1 was required for A20 effector function because A20 was defective for the targeting and inactivation of TBK1 and IKKi in Tax1bp1(-)(/)(-) MEFs. Additionally, we found the E3 ubiquitin ligase TRAF3 to play a critical role in promoting TBK1-IKKi ubiquitination. Collectively, our results demonstrate TBK1-IKKi to be novel substrates for A20 and further identify a novel mechanism whereby A20 and TAX1BP1 restrict antiviral signaling by disrupting a TRAF3-TBK1-IKKi signaling complex.

The role of mitochondria in the mammalian antiviral defense system

Innate immunity is a crucial defense system against viral and bacterial pathogens, providing a rapid response to mitigate the effects of microbial attack. While more readily associated with respiration and metabolism, recent research has surprisingly identified a number of mitochondrial factors in the mammalian innate immune system. This review summarizes the novel mitochondrial proteins, such as MAVS and NLRX1, involved in this process and attempts to reconcile this new mitochondrial function with our previous knowledge of the organelle.

Stimulator of IFN gene is critical for induction of IFN-beta during Chlamydia muridarum infection

Type I IFN signaling has recently been shown to be detrimental to the host during infection with Chlamydia muridarum in both mouse lung and female genital tract. However, the pattern recognition receptor and the signaling pathways involved in chlamydial-induced IFN-beta are unclear. Previous studies have demonstrated no role for TLR4 and a partial role for MyD88 in chlamydial-induced IFN-beta. In this study, we demonstrate that mouse macrophages lacking TLR3, TRIF, TLR7, or TLR9 individually or both TLR4 and MyD88, still induce IFN-beta equivalent to wild type controls, leading to the hypothesis that TLR-independent cytosolic pathogen receptor pathways are crucial for this response. Silencing nucleotide-binding oligomerization domain 1 in HeLa cells partially decreased chlamydial-induced IFN-beta. Independently, small interfering RNA-mediated knockdown of the stimulator of IFN gene (STING) protein in HeLa cells and mouse oviduct epithelial cells significantly decreased IFN-beta mRNA expression, suggesting a critical role for STING in chlamydial-induced IFN-beta induction. Conversely, silencing of mitochondria-associated antiviral signaling proteins and the Rig-I-like receptors, RIG-I, and melanoma differentiation associated protein 5, had no effect. In addition, induction of IFN-beta depended on the downstream transcription IFN regulatory factor 3, and on activation of NF-kappaB and MAPK p38. Finally, STING, an endoplasmic reticulum-resident protein, was found to localize in close proximity to the chlamydial inclusion membrane during infection. These results indicate that C. muridarum induces IFN-beta via stimulation of nucleotide-binding oligomerization domain 1 pathway, and TLR- and Rig-I-like receptor-independent pathways that require STING, culminating in activation of IFN regulatory factor 3, NF-kappaB, and p38 MAPK.

Mitochondrial dynamics regulate the RIG-I-like receptor antiviral pathway

The intracellular retinoic acid-inducible gene I-like receptors (RLRs) sense viral ribonucleic acid and signal through the mitochondrial protein mitochondrial antiviral signalling (MAVS) to trigger the production of type I interferons and proinflammatory cytokines. In this study, we report that RLR activation promotes elongation of the mitochondrial network. Mimicking this elongation enhances signalling downstream from MAVS and favours the binding of MAVS to stimulator of interferon genes, an endoplasmic reticulum (ER) protein involved in the RLR pathway. By contrast, enforced mitochondrial fragmentation dampens signalling and reduces the association between both proteins. Our finding that MAVS is associated with a pool of mitofusin 1, a protein of the mitochondrial fusion machinery, suggests that MAVS is capable of regulating mitochondrial dynamics to facilitate the mitochondria-ER association required for signal transduction. Importantly, we observed that viral mitochondria-localized inhibitor of apoptosis, a cytomegalovirus (CMV) antiapoptotic protein that promotes mitochondrial fragmentation, inhibits signalling downstream from MAVS, suggesting a possible new immune modulation strategy of the CMV.

STING-ing the antiviral pathway

The cytosolic DNA sensing pathway has remained poorly defined thus far. A recent study by Ishikawa et al. demonstrates that STING is essential for DNA-mediated type I IFN production and host defence against DNA pathogens.

Atg9a controls dsDNA-driven dynamic translocation of STING and the innate immune response

Microbial nucleic acids are critical for the induction of innate immune responses, a host defense mechanism against infection by microbes. Recent studies have indicated that double-stranded DNA (dsDNA) induces potent innate immune responses via the induction of type I IFN (IFN) and IFN-inducible genes. However, the regulatory mechanisms underlying dsDNA-triggered signaling are not fully understood. Here we show that the translocation and assembly of the essential signal transducers, stimulator of IFN genes (STING) and TANK-binding kinase 1 (TBK1), are required for dsDNA-triggered innate immune responses. After sensing dsDNA, STING moves from the endoplasmic reticulum (ER) to the Golgi apparatus and finally reaches the cytoplasmic punctate structures to assemble with TBK1. The addition of an ER-retention signal to the C terminus of STING dampens its ability to induce antiviral responses. We also show that STING co-localizes with the autophagy proteins, microtubule-associated protein 1 light chain 3 (LC3) and autophagy-related gene 9a (Atg9a), after dsDNA stimulation. The loss of Atg9a, but not that of another autophagy-related gene (Atg7), greatly enhances the assembly of STING and TBK1 by dsDNA, leading to aberrant activation of the innate immune response. Hence Atg9a functions as a regulator of innate immunity following dsDNA stimulation as well as an essential autophagy protein. These results demonstrate that dynamic membrane traffic mediates the sequential translocation and assembly of STING, both of which are essential processes required for maximal activation of the innate immune response triggered by dsDNA.

PCBP2 mediates degradation of the adaptor MAVS via the HECT ubiquitin ligase AIP4

MAVS is critical in innate antiviral immunity as the sole adaptor for RIG-I-like helicases. MAVS regulation is essential for the prevention of excessive harmful immune responses. Here we identify PCBP2 as a negative regulator in MAVS-mediated signaling. Overexpression of PCBP2 abrogated cellular responses to viral infection, whereas knockdown of PCBP2 exerted the opposite effect. PCBP2 was induced after viral infection, and its interaction with MAVS led to proteasomal degradation of MAVS. PCBP2 recruited the HECT domain-containing E3 ligase AIP4 to polyubiquitinate and degrade MAVS. MAVS was degraded after viral infection in wild-type mouse embryonic fibroblasts but remained stable in AIP4-deficient (Itch(-/-)) mouse embryonic fibroblasts, coupled with greatly exaggerated and prolonged antiviral responses. The PCBP2-AIP4 axis defines a new signaling cascade for MAVS degradation and 'fine tuning' of antiviral innate immunity.