In Vivo Ligands of MDA5 and RIG-I in Measles Virus-Infected Cells

RIG-I-like receptors (RLRs: RIG-I, MDA5 and LGP2) play a major role in the innate immune response against viral infections and detect patterns on viral RNA molecules that are typically absent from host RNA. Upon RNA binding, RLRs trigger a complex downstream signaling cascade resulting in the expression of type I interferons and proinflammatory cytokines. In the past decade extensive efforts were made to elucidate the nature of putative RLR ligands. In vitro and transfection studies identified 5′-triphosphate containing blunt-ended double-strand RNAs as potent RIG-I inducers and these findings were confirmed by next-generation sequencing of RIG-I associated RNAs from virus-infected cells. The nature of RNA ligands of MDA5 is less clear. Several studies suggest that double-stranded RNAs are the preferred agonists for the protein. However, the exact nature of physiological MDA5 ligands from virus-infected cells needs to be elucidated. In this work, we combine a crosslinking technique with next-generation sequencing in order to shed light on MDA5-associated RNAs from human cells infected with measles virus. Our findings suggest that RIG-I and MDA5 associate with AU-rich RNA species originating from the mRNA of the measles virus L gene. Corresponding sequences are poorer activators of ATP-hydrolysis by MDA5 in vitro, suggesting that they result in more stable MDA5 filaments. These data provide a possible model of how AU-rich sequences could activate type I interferon signaling.     

The ubiquitin ligase Riplet is essential for RIG-I-dependent innate immune responses to RNA virus infection

RNA virus infection is recognized by the RIG-I-like receptors RIG-I and MDA5, which induce antiviral responses including the production of type I interferons (IFNs) and proinflammatory cytokines. RIG-I is regulated by Lys63-linked polyubiquitination, and three E3 ubiquitin ligases, RNF125, TRIM25, and Riplet, are reported to target RIG-I for ubiquitination. To examine the importance of Riplet in?vivo, we generated Riplet-deficient mice. Fibroblasts, macrophages, and conventional dendritic cells from Riplet-deficient animals were defective for the production of IFN and other cytokines in response to infection with several RNA viruses. However, Riplet was dispensable for the production of IFN in response to B-DNA and DNA virus infection. Riplet deficiency abolished RIG-I activation during RNA virus infection, and the mutant mice were more susceptible to vesicular stomatitis virus infection than wild-type mice. These data indicate that Riplet is essential for regulating RIG-I-mediated innate immune response against RNA virus infection in?vivo.     

The Essential,Nonredundant Roles of RIG-I and MDA5 in Detecting and Controlling West Nile Virus Infection

Virus recognition and response by the innate immune system are critical components of host defense against infection. Activation of cell-intrinsic immunity and optimal priming of adaptive immunity against West Nile virus (WNV), an emerging vector-borne virus, depend on recognition by RIG-I and MDA5, two cytosolic pattern recognition receptors (PRRs) of the RIG-I-like receptor (RLR) protein family that recognize viral RNA and activate defense programs that suppress infection. We evaluated the individual functions of RIG-I and MDA5 both in vitro and in vivo in pathogen recognition and control of WNV. Lack of RIG-I or MDA5 alone results in decreased innate immune signaling and virus control in primary cells in vitro and increased mortality in mice. We also generated RIG-I^−/− × MDA5^−/− double-knockout mice and found that a lack of both RLRs results in a complete absence of innate immune gene induction in target cells of WNV infection and a severe pathogenesis during infection in vivo, similar to findings for animals lacking MAVS, the central adaptor molecule for RLR signaling. We also found that RNA products from WNV-infected cells but not incoming virion RNA display at least two distinct pathogen-associated molecular patterns (PAMPs) containing 5′ triphosphate and double-stranded RNA that are temporally distributed and sensed by RIG-I and MDA5 during infection. Thus, RIG-I and MDA5 are essential PRRs that recognize distinct PAMPs that accumulate during WNV replication. Collectively, these experiments highlight the necessity and function of multiple related, cytoplasmic host sensors in orchestrating an effective immune response against an acute viral infection.     

A novel selective autophagy receptor,CCDC50, delivers K63 polyubiquitination-activated RIG-I/MDA5 for degradation during viral infection

Autophagy is a conserved process that delivers cytosolic substances to the lysosome for degradation, but its direct role in the regulation of antiviral innate immunity remains poorly understood. Here, through high-throughput screening, we discovered that CCDC50 functions as a previously unknown autophagy receptor that negatively regulates the type I interferon (IFN) signaling pathway initiated by RIG-I-like receptors (RLRs), the sensors for RNA viruses. The expression of CCDC50 is enhanced by viral infection, and CCDC50 specifically recognizes K63-polyubiquitinated RLRs, thus delivering the activated RIG-I/MDA5 for autophagic degradation. The association of CCDC50 with phagophore membrane protein LC3 is confirmed by crystal structure analysis. In contrast to other known autophagic cargo receptors that associate with either the LIR-docking site (LDS) or the UIM-docking site (UDS) of LC3, CCDC50 can bind to both LDS and UDS, representing a new type of cargo receptor. In mouse models with RNA virus infection, CCDC50 deficiency reduces the autophagic degradation of RIG-I/MDA5 and promotes type I IFN responses, resulting in enhanced viral resistance and improved survival rates. These results reveal a new link between autophagy and antiviral innate immune responses and provide additional insights into the regulatory mechanisms of RLR-mediated antiviral signaling.Subject terms: Macroautophagy, Ubiquitylation, RIG-I-like receptors     

Identification of Loss of Function Mutations in Human Genes Encoding RIG-I and MDA5: IMPLICATIONS FOR RESISTANCE TO TYPE I DIABETES*

Retinoic acid-inducible gene I (RIG-I) and melanoma differentiation-associated gene 5 (MDA5) are essential for detecting viral RNA and triggering antiviral responses, including production of type I interferon. We analyzed the phenotype of non-synonymous mutants of human RIG-I and MDA5 reported in databases by functional complementation in cell cultures. Of seven missense mutations of RIG-I, S183I, which occurs within the second caspase recruitment domain repeat, inactivated this domain and conferred a dominant inhibitory function. Of 10 mutants of MDA5, two exhibited loss of function. A nonsense mutation, E627*, resulted in deletion of the C-terminal region and double-stranded RNA (dsRNA) binding activity. Another loss of function mutation, I923V, which occurs within the C-terminal domain, did not affect dsRNA binding activity, suggesting a novel and essential role for this residue in the signaling. Remarkably, these mutations are implicated in resistance to type I diabetes. However, the A946T mutation of MDA5, which has been implicated in type I diabetes by previous genetic analyses, affected neither dsRNA binding nor IFN gene activation. These results provide new insights into the structure-function relationship of RIG-I-like receptors as well as into human RIG-I-like receptor polymorphisms, antiviral innate immunity, and autoimmune diseases.Innate and adaptive immune systems constitute the defense against infections by pathogens. Immediately after an infection occurs, various cells in the body sense the virus and initiate antiviral responses in which type I IFN² plays a critical role, both in viral inhibition and in the subsequent adaptive immune response (1). The production of IFN is initiated when sensor molecules such as Toll-like receptors (TLRs) and RLRs detect virus-associated molecules. TLRs detect pathogen-associated molecular patterns (PAMPs) at the cell surface or in the endosome in immune cells such as dendritic cells and macrophages (2). RLRs sense viral RNA in the cytoplasm of most cell types and induce antiviral responses, including the activation of IFN genes (3). RLRs include RIG-I, MDA5, and laboratory of genetics and physiology 2 (LGP2).It is proposed that RLRs sense and activate antiviral signals through the coordination of their functional domains (4). The N-terminal region of RIG-I and MDA5 is characterized by two repeats of CARD and functions as an activation domain (3). This domain is responsible for the transduction of signals downstream to IFN-β promoter stimulator 1 (IPS-1) (also known as MAVS, VISA, and Cardif). The primary sequence of the CTD, consisting of ∼140 amino acids, is conserved among RLRs. The CTD of RIG-I functions as a viral RNA-sensing domain as revealed by biochemical and structural analyses (5, 6). Both dsRNA and 5′-ppp-ssRNA, which are generated in the cytoplasm of virus-infected cells, are recognized by a basic cleft structure of RIG-I CTD. In addition to its RNA recognition function, the CTD of RIG-I and LGP2 functions as a repression domain through interaction with the activation domain. The repression domain is responsible for keeping RIG-I inactive in non-stimulated cells (3, 7). The helicase domain, with DEXD/H box-containing RNA helicase motifs, is the largest domain found in RLRs. Once dsRNA or 5′-ppp-ssRNA is recognized by the CTD, the helicase domain causes structural changes to release the activation domain. ATP binding and/or its hydrolysis is essential for the conformational change because Walker''s ATP-binding site within the helicase domain is essential for signaling by RIG-I and MDA5.Analyses of knock-out mice have revealed that RIG-I and MDA5 recognize distinct RNA viruses (8, 9). Picornaviruses are detected by MDA5, but many other viruses such as influenza A, Sendai, vesicular stomatitis, and Japanese encephalitis are detected by RIG-I. The difference is based on the distinct non-self RNA patterns generated by viruses, as demonstrated by the finding that RIG-I is selectively activated by dsRNA or 5′-ppp ssRNA, whereas MDA5 is activated by long dsRNA (10–12).Single nucleotide polymorphisms (SNPs) of the human RIG-I and MDA5 genes including several non-synonymous SNPs (nsSNPs), which potentially alter the function of the proteins encoded, are reported in databases. In this report, we investigated the functions of nsSNPs of RIG-I and MDA5 by functional complementation using respective knock-out cells. We identified loss of function mutations of RIG-I and MDA5. Notably, two MDA5 mutations, E627* and I923V, recently reported to have a strong association with resistance to T1D (13), were severely inactive. The results suggest a novel molecular mechanism for the activation of RLRs and will contribute to our understanding of the functional effects of RLR polymorphisms and the critical relationship between RLR nsSNPs and diseases.     

Positive Evolutionary Selection On the RIG-I-Like Receptor Genes in Mammals

The mammalian RIG-I-like receptors, RIG-I, MDA5 and LGP2, are a family of DExD/H box RNA helicases responsible for the cytoplasmic detection of viral RNA. These receptors detect a variety of RNA viruses, or DNA viruses that express unusual RNA species, many of which are responsible for a great number of severe and lethal diseases. Host innate sentinel proteins involved in pathogen recognition must rapidly evolve in a dynamic arms race with pathogens, and thus are subjected to long-term positive selection pressures to avoid potential infections. Using six codon-based Maximum Likelihood methods, we were able to identify specific codons under positive selection in each of these three genes. The highest number of positively selected codons was detected in MDA5, but a great percentage of these codons were located outside of the currently defined protein domains for MDA5, which likely reflects the imposition of both functional and structural constraints. Additionally, our results support LGP2 as being the least prone to evolutionary change, since the lowest number of codons under selection was observed for this gene. On the other hand, the preponderance of positively selected codons for RIG-I were detected in known protein functional domains, suggesting that pressure has been imposed by the vast number of viruses that are recognized by this RNA helicase. Furthermore, the RIG-I repressor domain, the region responsible for recognizing and binding to its RNA substrates, exhibited the strongest evidence of selective pressures. Branch-site analyses were performed and several species branches on the three receptor gene trees showed evidence of episodic positive selection. In conclusion, by looking for evidence of positive evolutionary selection on mammalian RIG-I-like receptor genes, we propose that a multitude of viruses have crafted the receptors biological function in host defense, specifically for the RIG-I gene, contributing to the innate species-specific resistance/susceptibility to diverse viral pathogens.     

Regulation of RLR-mediated innate immune signaling--it is all about keeping the balance

The current view of cytoplasmic RNA-mediated innate immune signaling involves the differential activation of the RNA helicases retinoic acid-inducible gene 1 (RIG-I), melanoma differentiation-associated gene 5 (MDA5) and laboratory of genetics and physiology-2 (LGP2) by distinct RNA viruses. RIG-I, MDA5 and LGP2 form the RIG-I like receptor family (RLR). Since the initial characterization of the RLRs rapid progress has been made in the understanding of the molecular mechanisms that upon virus infection lead to the activation of downstream signaling cascades and the subsequent induction of type I interferon (IFN) and proinflammatory cytokines by these receptors. However, antiviral responses must be tightly regulated in order to prevent uncontrolled production of type I IFN that might have deleterious effects on the host. Exploring the structural and molecular mechanisms that underlie RLR signaling thus was accompanied by the discovery of how RLR-dependent antiviral responses are modulated. This article summarizes the current understanding of endogenous regulation in RLR signaling by various intrinsic molecules that exert their regulatory function in both the steady state or upon viral infection by targeting multiple steps of the signaling cascade.     

Negative Regulation of Melanoma Differentiation-associated Gene 5 (MDA5)-dependent Antiviral Innate Immune Responses by Arf-like Protein 5B

RIG-I-like receptors (RLRs), including retinoic acid-inducible gene-I (RIG-I) and MDA5, constitute a family of cytoplasmic RNA helicases that senses viral RNA and mounts antiviral innate immunity by producing type I interferons and inflammatory cytokines. Despite their essential roles in antiviral host defense, RLR signaling is negatively regulated to protect the host from excessive inflammation and autoimmunity. Here, we identified ADP-ribosylation factor-like protein 5B (Arl5B), an Arl family small GTPase, as a regulator of RLR signaling through MDA5 but not RIG-I. Overexpression of Arl5B repressed interferon β promoter activation by MDA5 but not RIG-I, and its knockdown enhanced MDA5-mediated responses. Furthermore, Arl5B-deficient mouse embryonic fibroblast cells exhibited increased type I interferon expression in response to MDA5 agonists such as poly(I:C) and encephalomyocarditis virus. Arl5B-mediated negative regulation of MDA5 signaling does not require its GTP binding ability but requires Arl5B binding to the C-terminal domain of MDA5, which prevents interaction between MDA5 and poly(I:C). Our results, therefore, suggest that Arl5B is a negative regulator for MDA5.     

Melanoma Differentiation-Associated Gene 5 (MDA5) Is Involved in the Innate Immune Response to Paramyxoviridae Infection In Vivo

The early host response to pathogens is mediated by several distinct pattern recognition receptors. Cytoplasmic RNA helicases including RIG-I and MDA5 have been shown to respond to viral RNA by inducing interferon (IFN) production. Previous in vitro studies have demonstrated a direct role for MDA5 in the response to members of the Picornaviridae, Flaviviridae and Caliciviridae virus families ((+) ssRNA viruses) but not to Paramyxoviridae or Orthomyxoviridae ((−) ssRNA viruses). Contrary to these findings, we now show that MDA5 responds critically to infections caused by Paramyxoviridae in vivo. Using an established model of natural Sendai virus (SeV) infection, we demonstrate that MDA5^−/− mice exhibit increased morbidity and mortality as well as severe histopathological changes in the lower airways in response to SeV. Moreover, analysis of viral propagation in the lungs of MDA5^−/− mice reveals enhanced replication and a distinct distribution involving the interstitium. Though the levels of antiviral cytokines were comparable early during SeV infection, type I, II, and III IFN mRNA expression profiles were significantly decreased in MDA5^−/− mice by day 5 post infection. Taken together, these findings indicate that MDA5 is indispensable for sustained expression of IFN in response to paramyxovirus infection and provide the first evidence of MDA5-dependent containment of in vivo infections caused by (−) sense RNA viruses.     

Innate immune response to RNA virus infection

Viral RNA is recognized by RIG-I-like receptors and Toll-like receptors. RIG-I is a cytoplasmic viral RNA sensor. High Mobility Group Box (HMGB) proteins and DExD/H box RNA helicases, such as DDX3 and 60, associate with viral RNA. Those proteins promotes the RIG-I binding to viral RNA. RIG-I triggers the signal via IPS-1 adaptor molecule to induce type I IFN. RIG-I harbors Lys63-linked polyubiquitination by Riplet and TRIM25 ubiquitin ligases. The polyubiquitination is essential for RIG-I-mediated signaling. Toll-like receptors are located in endosome. TLR3 recognizes viral double-stranded RNA, and TLR7 and 8 recognize single-strand RNA. Virus has the ability to suppress these innate immune response. For example, to inhibit RIG-I-mediated signaling, HCV core protein suppresses the function of DDX3. In addition, HCV NS3-4A protein cleaves IPS-1 to inhibit the signal. Molecular mechanism of how viral RNA is recognized by innate immune system will make great progress on our understanding of how virus escapes from host immune system.     

鱼类和哺乳类RLR介导的抗病毒免疫反应的泛素化修饰调控

RLR[retinoic acid-inducible gene Ⅰ(RIG-Ⅰ)-like Receptors]是一类表达在胞浆中的模式识别受体, 在识别细胞质中经病毒复制产生的病毒RNA后, 启动一系列信号级联反应, 以诱导机体Ⅰ型干扰素及干扰素诱导的抗病毒基因的表达, 最后达到清除机体病毒感染的目的。由于在病毒感染时机体干扰素反应必须迅速启动, 当病毒清除后干扰素反应又需要立即恢复到正常本底水平, 因此RLR激活的信号转导途径受到了严格的调控, 其中就包括由E3泛素连接酶参与的泛素化修饰调控和由去泛素化酶参与的去泛素化修饰调控。自2003年成功鉴定出鱼类干扰素基因以来, 鱼类也被发现具有保守的RLR信号转导途径诱导干扰素抗病毒免疫反应, 该信号途径同样受到泛素化修饰的调控。文章总结了近年来泛素化修饰在哺乳类和鱼类RLR介导的抗病毒免疫应答通路中的调节机制。     

Establishment and maintenance of the innate antiviral response to West Nile Virus involves both RIG-I and MDA5 signaling through IPS-1

RIG-I and MDA5, two related pathogen recognition receptors (PRRs), are known to be required for sensing various RNA viruses. Here we investigated the roles that RIG-I and MDA5 play in eliciting the antiviral response to West Nile virus (WNV). Functional genomics analysis of WNV-infected fibroblasts from wild-type mice and RIG-I null mice revealed that the normal antiviral response to this virus occurs in two distinct waves. The initial response to WNV resulted in the expression of interferon (IFN) regulatory factor 3 target genes and IFN-stimulated genes, including several subtypes of alpha IFN. Subsequently, a second phase of IFN-dependent antiviral gene expression occurred very late in infection. In cells lacking RIG-I, both the initial and the secondary responses to WNV were delayed, indicating that RIG-I plays a critical role in initiating innate immunity against WNV. However, another PRR(s) was able to trigger a response to WNV in the absence of RIG-I. Disruption of both MDA5 and RIG-I pathways abrogated activation of the antiviral response to WNV, suggesting that MDA5 is involved in the host's defense against WNV infection. In addition, ablation of the function of IPS-1, an essential RIG-I and MDA5 adaptor molecule, completely disabled the innate antiviral response to WNV. Our data indicate that RIG-I and MDA5 are responsible for triggering downstream gene expression in response to WNV infection by signaling through IPS-1. We propose a model in which RIG-I and MDA5 operate cooperatively to establish an antiviral state and mediate an IFN amplification loop that supports immune effector gene expression during WNV infection.