Select Paramyxoviral V Proteins Inhibit IRF3 Activation by Acting as Alternative Substrates for Inhibitor of κB Kinase ϵ (IKKe)/TBK1

Lu, Lenette L.; Puri, Mamta; Horvath, Curt M.; Sen, Ganes C.

doi:10.1074/jbc.m710089200

Cited by 84 publications

(77 citation statements)

References 41 publications

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“…MV replicates in the cytoplasm and activates the RIG-I sensor due to the presence of cytosolic 5Ј-triphosphate-containing viral transcripts (24,25), but paradoxically, the V protein of MV blocks the mda-5 sensor of the RLR IFN-␤ induction pathway (6,18). Furthermore, TLR3 signaling through the adapter TRIF is impaired by V proteins of rubulaviruses but not by the MV V protein (14). Both the cytoplasmic RLRs and membrane-bound TLR3 act as sensors of viral dsRNA to initiate the innate immune response and IFN induction.…”

Section: Irf-3 Phosphorylation Is Enhanced In C Ko -Infected Comparedmentioning

confidence: 99%

Mechanisms of Protein Kinase PKR-Mediated Amplification of Beta Interferon Induction by C Protein-Deficient Measles Virus

McAllister

Toth

Zhang

et al. 2010

J Virol

106

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The measles virus P gene products V and C antagonize the host interferon (IFN) response, blocking both IFN signaling and production. Using Moraten vaccine strain-derived measles virus and isogenic mutants deficient for either V or C protein production (V ko and C ko , respectively), we observed that the C Measles virus (MV), a member of the genus Morbillivirus of the Paramyxoviridae, causes an acute febrile illness. Despite an effective vaccine, measles continues to cause extreme morbidity and mortality worldwide (10), and recently, there has been a resurgence of measles in industrialized countries, where a lack of adherence to vaccine recommendations is an increasing problem (5, 12). The need for improved MV vaccines (11), together with the potential for use of engineered MV vaccine strains with defined mechanisms of attenuation as oncolytic viruses for cancer therapy (4), further justify ongoing efforts to gain an enhanced understanding of the host response to MV infection at the molecular level.The 15.9-kb negative-stranded RNA genome of MV consists of six genes (N, P/V/C, M, F, H, and L). The P gene is polycistronic, encoding the V and C nonstructural proteins in addition to P, a structural phosphoprotein and essential cofactor for the viral polymerase (2, 3, 10). The V protein shares its N-terminal 231 amino acids with P, but the C-terminal 68 amino acids are unique because of the pseudotemplated G insertion that causes a frameshift in V mRNA, whereas the C protein is synthesized by an alternative translation initiation AUG codon positioned 22 nucleotides downstream of the P/V translation start codon (3, 11). V and C are accessory proteins that serve a variety of functions including the modulation of the host innate immune response to MV infection (8, 9, 27). Isogenic MV mutants that are defective for the expression of either V or C have been generated. Strong adaptive immune responses, but dysregulated innate responses, are seen with these mutants (4,8,35).An important component of the host innate antiviral response is the interferon (IFN) response. IFNs are proinflammatory cytokines that possess antiviral activity (27,31). IFN action involves IFN binding to cognate receptors and subsequent prototypical JAK-STAT signal transduction that leads to the expression of IFN-stimulated genes, whose products inhibit virus growth. IFN production involves the recognition of pathogen-associated molecular patterns including viral RNAs by retinoic acid-inducible protein (RIG-I)-like cytosolic receptors (RLRs) and membrane-associated Toll-like receptors (TLRs). The RLR and TLR3 sensors signal through cognate adapter proteins, including IPS-1 and TRIF, respectively, to transcriptionally activate IFN expression (36,40). In the case of the IFN-␤ gene, IFN regulatory factor 3 (IRF-3) and nuclear factor B (NF-B) are activated by RLR or TLR signaling, enter the nucleus, and function together with activating transcription factor 2 (ATF-2)/c-jun to constitute the IFN-␤ enhanceosome that drives IFN-␤ transcription (22).The antago...

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Section: Irf-3 Phosphorylation Is Enhanced In C Ko -Infected Comparedmentioning

confidence: 99%

Mechanisms of Protein Kinase PKR-Mediated Amplification of Beta Interferon Induction by C Protein-Deficient Measles Virus

McAllister

Toth

Zhang

et al. 2010

J Virol

106

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“…This raises the possibility that paramyxoviruses have other mechanisms to block signaling responses through RIG-I. In this context, it has recently been reported that SeV-C can block RIG-I (28) and that some paramyxovirus V proteins, including PIV5-V, can block IRF-3 phosphorylation by interacting with IKKε/TBK1 and acting as alternative substrates (16). The latter phenomenon is presumably cell type specific, since we have failed to observe the expected inhibition of RIG-I by PIV5-V (2), and furthermore PIV5-V does not block induction by overexpression of the CARD domains of mda-5 or IPS-1 (Fig.…”

Section: Vol 83 2009 Mda-5 Inhibition By Paramyxovirus V Proteins 1471mentioning

confidence: 99%

Mechanism of mda-5 Inhibition by Paramyxovirus V Proteins

Childs

Andrejeva

Randall

et al. 2009

J Virol

114

135

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The RNA helicases encoded by melanoma differentiation-associated gene 5 (mda-5) and retinoic acidinducible gene I (RIG-I) detect foreign cytoplasmic RNA molecules generated during the course of a virus infection, and their activation leads to induction of type I interferon synthesis. Paramyxoviruses limit the amount of interferon produced by infected cells through the action of their V protein, which binds to and inhibits mda-5. Here we show that activation of both mda-5 and RIG-I by double-stranded RNA (dsRNA) leads to the formation of homo-oligomers through self-association of the helicase domains. We identify a region within the helicase domain of mda-5 that is targeted by all paramyxovirus V proteins and demonstrate that they inhibit activation of mda-5 by blocking dsRNA binding and consequent self-association. In addition to this commonly targeted domain, some paramyxovirus V proteins target additional regions of mda-5. In contrast, V proteins cannot bind to RIG-I and consequently have no effect on the ability of RIG-I to bind dsRNA or to form oligomers.Mammalian cells contain a variety of pattern recognition receptors that recognize foreign macromolecules termed pathogenassociated molecular patterns (PAMPs). Viral PAMPs generated in the cytosol during replication are recognized by the DExD/H-box RNA helicases coded for by melanoma differentiation-associated gene 5 (mda-5) and retinoic acid-inducible gene I (RIG-I) (reviewed in reference 30) and stimulate the production of type I interferon (IFN), which constitutes a major component of the innate immune response to virus infection (reviewed in reference 21). It is becoming clear that viruses generate a variety of different PAMPs and that, rather than being redundant, mda-5 and RIG-I show ligand specificity and are therefore differentially sensitive to activation by different viruses. For example, RIG-I seems to be more important for IFN induction in response to hepatitis C virus (HCV) (6, 24) and influenza A virus (12, 19), while mda-5 is necessary for responses to picornaviruses (7,12). Both mda-5 and RIG-I can be activated by the synthetic double-stranded RNA (dsRNA) poly(I-C), but a recent study suggests that the length of the dsRNA influences whether IFN induction is dependent on mda-5 or RIG-I, with mda-5 being more important for induction by long dsRNA and RIG-I more important for induction by short dsRNA (11). In addition to length, other structural features of viral RNAs can also determine receptor activation. For example, single-stranded RNA (ssRNA) and dsRNA molecules bearing a 5Ј triphosphate induce IFN via RIG-I and not mda-5 (10, 19). This motif is recognized as nonself, since most cellular RNAs are either capped or have a 5Ј monophosphate. IFN induction by RNA purified from influenza A virus, vesicular stomatitis virus, and rabies virus requires RIG-I and is dependent on the presence of a 5Ј triphosphate, underlining the importance of this motif as a genuine viral PAMP (8,10,19).mda-5 and RIG-I share a common domain structure with two tandem C...

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“…Rubulaviruses including MuV, hPIV2, and PIV5 use V protein as a decoy substrate for the IRF-3 kinases TANK-binding kinase 1 (TBK-1) and inhibitor of NF-κB kinase (IKK)e (Figure 3), both inhibiting phosphorylation of IRF-3 and facilitating IKKe/TBK-1 polyubiquitination and degradation to prevent further signalling [81] . Henipavirus V proteins do not cause IKKe/TBK-1 degradation [81] or block TLR-3/IRF-3 dependent signalling [76,81] . For henipaviruses, this appears to be a function of the W protein, as NiV W, although having no effect on MDA5 signalling, inhibited TLR-3-dependent phosphorylation of IRF-3 [82] .…”

Section: Inhibition Of Irf-3 Activationmentioning

confidence: 99%