Measles Virus V Protein Is a Decoy Substrate for I{kappa}B Kinase {alpha} and Prevents Toll-Like Receptor 7/9-Mediated Interferon Induction

The central role of plasmacytoid dendritic cells (pDC) in activatinghost immune responses stems from their high capacity to expressalpha interferon (IFN- ${alpha}$ ) after stimulation of Toll-like receptors7 and 9 (TLR7 and -9). This involves the adapter MyD88 and thekinases interleukin-1 receptor-associated kinase 1 (IRAK1),IRAK4, and I ${kappa}$ B kinase ${alpha}$ (IKK ${alpha}$ ), which activates IFN regulatoryfactor 7 (IRF7) and is independent of the canonical kinasesTBK1 and IKK ${varepsilon}$ . We have recently shown that the immunosuppressivemeasles virus (MV) abolishes TLR7/9/MyD88-dependent IFN inductionin human pDC (Schlender et al., J. Virol. 79:5507-5515, 2005),but the molecular mechanisms remained elusive. Here, we havereconstituted the pathway in cell lines and identified IKK ${alpha}$ andIRF7 as specific targets of the MV V protein (MV-V). Bindingof MV-V to IKK ${alpha}$ resulted in phosphorylation of V on the expenseof IRF7 phosphorylation by IKK ${alpha}$ in vitro and in living cells.This corroborates the role of IKK ${alpha}$ as the kinase phosphorylatingIRF7. MV-V in addition bound to IRF7 and to phosphomimetic IRF7and inhibited IRF7 transcriptional activity. Binding to bothIKK ${alpha}$ and IRF7 required the 68-amino-acid unique C-terminal domainof V. Inhibition of TLR/MyD88-dependent IFN induction by MV-Vis unique among paramyxovirus V proteins and should contributeto the unique immunosuppressive phenotype of measles. The mechanismsemployed by MV-V inspire strategies to interfere with immunopathologicalTLR/MyD88 signaling.

INTRODUCTION

Top

INTRODUCTION

Measles virus (MV) is an important human pathogen that inducesa generalized transient immune suppression which accounts formost of the mortality associated with measles as well as a specificimmune response that provides life-long protection (41). Thisparadoxical effect is most likely due to early interactionsof MV with cells of the immune system, including conventionaland plasmacytoid dendritic cells (cDC and pDC, respectively).Manifold functions of DC are compromised by MV infection, whichis proposed to contribute to immune suppression (19). A particularlyremarkable feature of MV is the ability to shut down alpha interferon(IFN- ${alpha}$ ) production in response to Toll-like receptor 7 (TLR7)and TLR9 ligands in infected human pDC in vitro, as we couldshow previously (48).

Human pDC are responsible for the bulk of early IFN productionin response to virus infection and for stimulation of importantadaptive immune response mechanisms (for reviews, see references8 and 18). The capacity of pDC for instant expression of hugeamounts of IFN- ${alpha}$ stems from a special signaling cascade activatingIFN regulatory factor 7 (IRF7) upon TLR7/9 stimulation (25,33). This relies on the presence of latent IRF7 (26) and high-levelexpression of the endosomal TLR7 and -9 (28). Agonists of TLR7and -9 include single-stranded RNA (ssRNA) and DNA, respectively,as well as nucleic acid derivatives which are being used asimmune modulators and adjuvants (22, 23). After ligation ofTLR7/9, IRF7 is recruited and phosphorylated in a complex includingthe Toll-interleukin-1 (IL-1) receptor (TIR) adapter MyD88,the E3-ubiquitin ligases tumor necrosis factor receptor-associatedfactor 3 (TRAF3) and TRAF6, and the kinases IL-1 receptor-associatedkinase 1 (IRAK1) and IRAK4 (24, 25, 33, 34, 59, 60). AlthoughIRAK1 was originally implicated in phosphorylation of IRF7,a recent report suggested this role for I ${kappa}$ B kinase ${alpha}$ (IKK ${alpha}$ ) (29).Phosphorylated IRF7 dimerizes and is translocated to the nucleus,where it binds to the promoter of IFN- ${alpha}$ genes and upregulatestheir expression. Importantly, not only exogenous endocytosednucleic acids may stimulate TLR7/9 IFN signaling, but also intracellularcytoplasmic nucleic acids that have been engulfed by the processof autophagy and delivered to endosomes (37). In turn, TLR signalingstimulates autophagy, thereby improving recognition of cytoplasmicviral RNAs (14).

Apart from virus recognition by pDC and induction of antiviralimmunity, a critical role of TLR7/9 signaling in amplifyingautoimmune responses and sustaining autoimmune conditions hasbeen established. Recent studies have revealed inappropriateactivation of IFN by TLR7/9 in systemic lupus erythematosusand several other autoimmune diseases. Intriguingly, in thisrespect, it was shown that also cDC and macrophages can producehigh levels of IFN when the spatiotemporal regulation of MyD88/IRF7signaling is affected (24, 57), specifically, when the TLR ligandsare retained in or redirected to endosomes by autoimmune complexescontaining RNA and DNA (for recent reviews, see references 35and 36).

In order to further address TLR7-MyD88-dependent IFN- ${alpha}$ inductionand to reveal the counteracting mechanism(s) evolved by MV,we have restored the pathway in cell lines by expression ofindividual components from transfected plasmids. Biochemicaland reporter gene assays strongly support the direct involvementof IKK ${alpha}$ in IRF7 phosphorylation, which is corroborated by theidentification of IKK ${alpha}$ as a specific molecular target of theMV protein V (MV-V).

MV-V is expressed from the MV phosphoprotein (MV-P) gene bymRNA editing (9) and is composed of an N-terminal sequence identicalto that of the MV-P and a unique 68-amino-acid (aa) Cys-richand zinc-binding C-terminal domain (39, 45). The MV-V-specificC terminus was identified here as an autonomous targeting moduledirecting V to IKK ${alpha}$ and IRF7, while sequences of the common N-terminaldomain were necessary for potent inhibition of IRF7-mediatedIFN- ${alpha}$ promoter activation. Among the V proteins of paramyxoviruses,which share organization and several immune escape functions,MV-V is unique in targeting MyD88-dependent IKK ${alpha}$ /IRF7 activation.It is strongly suggested that this peculiar function of MV-Vcontributes to the peculiar immunopathology of measles.

MATERIALS AND METHODS

Top

MATERIALS AND METHODS

Cell lines. HEK-293, 293T, and Huh7.5 cells (kindly provided by C. Rice)were propagated in Dulbecco's minimal essential medium with10% fetal bovine serum, 1x L-glutamine, and penicillin-streptomycin(Invitrogen). BSR-T7/5 cells were propagated in Glasgow minimalessential medium with 10% newborn calf serum, 1x nonessentialamino acids, 1x tryptose-phosphate, and penicillin-streptomycin.

cDNA constructs. Open reading frames (ORFs) encoding MV-P and MV-V (Schwarz vaccinestrain) were cloned in pCR3 (Invitrogen). Expression of theC protein was abolished in pCR3-P ${Delta}$ C and pCR3-V ${Delta}$ C by exchange ofthree nucleotides by site-directed mutagenesis using primers1 and 2 (Table 1) and leading to disruption of the start codonand introduction of two stop codons.

View this table:
[in this window]
[in a new window]

TABLE 1. Primers used for cloning of cDNAs

Immunoglobulin (Ig)-tagged versions of MV-P, MV-V, and MV-Cwere generated by cloning EcoRI/NotI restriction fragments ofpCR3-P ${Delta}$ C, pCR3-V ${Delta}$ C, and pCR3-MV-C into pCR3-Ig (a modified pCR3vector expressing an Ig tag upstream of EcoRI). Ig-tagged proteindomains MV-PV_N (aa 1 to 231), MV-P_C (aa 232 to 507), and MV-V_C(aa 232 to 299) were generated by cloning PCR products frompCR3-P ${Delta}$ C and pCR3-V ${Delta}$ C into pCR3-Ig (EcoRI/XhoI) using primers3 to 8.

To generate vectors for bacterial expression, ORFs of MV-P,MV-V, and IRF7 were cloned in pET28a (Novagen), using the NheI/NotIrestriction sites and primers 9 to 12.

Bacterial expression and Ni-NTA purification. His-MV-P, His-MV-V, and His-IRF7 were expressed in Escherichiacoli BL21 Rosetta cells (Novagen) and purified by Ni-nitrilotriaceticacid (NTA) affinity chromatography as described elsewhere (13).

Transfection. For reporter gene assays, 1 x 10⁵ cells (Huh7.5, 293, or 293T)were seeded in 24-well microtiter plates. After 16 h, 100 ngof the firefly luciferase (FL) reporter plasmid p55C1B-Luc (kindlyprovided by T. Fujita), IFN ${alpha}$ 4-Luc, or IFN ${alpha}$ 6-Luc (kindly providedby S. Akira) was transfected using Lipofectamine 2000 transfectionreagent (Invitrogen). As an internal control, 10 ng of pCMV-RLwas cotransfected in all experiments. Various amounts of pCR3-P ${Delta}$ C,pCR3-V ${Delta}$ C, myc-MyD88 (K. Ruckdeschel), Fl-TRAF6 (A. Kieser), Fl-IKK ${alpha}$ (K. Ruckdeschel), Fl-IRF7 (murine from S. Akira and human fromJ. Hiscott), Fl-IRAK1, Fl-IRAK1c, Fl-IRAK4 (all from RZPD),and Fl-TBK1 were cotransfected as indicated. Amounts of transfectedDNA were adjusted by adding pCR3 or pCR3-Ig vector.

For coimmunoprecipitation experiments, HEK-293T cells were transfectedin 21-cm² dishes (2.6 x 10⁶ cells/dish) with 2 µg of Fl-IKK ${alpha}$ ,Fl-IKKβ (K. Ruckdeschel), Fl-IKK ${varepsilon}$ (J. Hiscott), Fl-TBK1,Fl-IRF7, Fl-IRF7-2D, Fl-IRF3, or Fl-IRF3-5D (J. Hiscott), aswell as 2 µg of Ig-tagged P/V/C constructs or domainsor with pCR3-Ig empty vector as indicated. Pull-down experimentswere performed 24 h posttransfection as previously described(5) using protein A-conjugated Sepharose beads (GE Healthcare)to pull down Ig-tagged proteins or anti-FLAG M2 affinity gel(Sigma) to pull down Flag-tagged proteins.

Luciferase assay. Cell lysates were prepared 24 h posttransfection and subjectedto reporter gene assay using the Promega dual-luciferase reportersystem. Luciferase activity was measured with a Luminometer(Berthold Centro LB 960 or Berthold Lumat LB 9501) accordingto the supplier's instructions. Graphs show mean values of atleast three independent experiments plus standard deviations.

Western blots and antibodies. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis wasperformed as previously described (5). Anti-MV-P (C terminus;#37069) was kindly provided by D. Gerlier (10), anti-MV-P (Nterminus; P3) was kindly provided by S. Schneider-Schaulies,and anti-MV-V (C terminus) and anti-MV-C were kindly providedby R. Cattaneo. Anti-Flag-M2 and anti-His were purchased fromSigma and Cell Signaling, respectively.

Blots shown are representative of at least three independentlyperformed experiments.

In vitro kinase assays. Kinase-active His-IKK ${alpha}$ (100 ng/reaction [Invitrogen]) was mixedwith purified His-IRF7 (500 ng/reaction) or glutathione S-transferase(GST)-I ${kappa}$ B- ${alpha}$ (100 ng/reaction [Santa Cruz]) and increasing amountsof His-MV-V or His-MV-P (0 to 1,600 pmol/reaction as indicated)in reaction buffer (50 mM HEPES, 0,01% Triton X-100, 10 mM MgCl₂,1 mM EGTA, 0.5 mM Na₃VO₄, 5 mM β-glycerophosphate, 2 mMdithiothreitol [DTT], pH 7.5). To start the reaction, 200 µMATP with tracing amounts of [ ${gamma}$ -³²P]ATP (Amersham) were addedto the reaction mix. The reaction was stopped by adding denaturingcell lysis buffer. Probes were subjected to 10% sodium dodecylsulfate-polyacrylamide gel electrophoresis and transferred toa nitrocellulose membrane. Radioactively labeled proteins weredetected by autoradiography using a Storm phosphorimager (GEHealthcare) and quantified by ImageQuant software (MolecularDynamics).

RESULTS

Top

RESULTS

Reconstitution of MyD88-dependent IFN- ${alpha}$ activation in cell lines. As the TLR7/9-mediated IFN- ${alpha}$ -inducing signaling pathway is operatingefficiently only in primary pDC, which are less amenable tobiochemical approaches, we sought to facilitate the analysisof the pathway by reconstitution in cell lines including BSR-T7/5,HEK-293, HEK-293T, and Huh7.5. First, activation of differentIFN- ${alpha}$ promoters ( ${alpha}$ 1, ${alpha}$ 4, and ${alpha}$ 6) after expression of human IRF7(hIRF7) and mouse IRF7 (mIRF7) from transfected plasmids wasdetermined (Fig. 1A). The activity of IFN ${alpha}$ 4- and IFN ${alpha}$ 6 promoter-controlledfirefly luciferase (FL) was conspicuously greater than thatof the IFN ${alpha}$ 1 promoter. In further experiments, the IFN ${alpha}$ 4 promoterwas used in combination with mIRF7, which activated all threepromoters better than hIRF7.

View larger version (31K):
[in this window]
[in a new window]

FIG. 1. Reconstitution of MyD88-dependent TLR7/9 signaling in cell lines. (A) 293T cells were transfected with the indicated plasmids, and activation of IFN- ${alpha}$ promoters was determined by dual-luciferase assay. Overexpression of mIRF7 (m) and hIRF7 (h) (450 ng of plasmid) leads to efficient induction of the IFN ${alpha}$ 4 and IFN ${alpha}$ 6 promoters and moderate induction of IFN ${alpha}$ 1. (B) TRAF6 and MyD88 expression increases the activity of mIRF7 in a dose-dependent manner. (C) Expression of IRAK1 or IRAK1c in addition to IRF7, MyD88, and TRAF6 leads to a dose-dependent inhibitory effect on IFN ${alpha}$ 4 promoter-driven FL activity. (D) Effect of indicated amounts of plasmids encoding for IRAK1, IRAK4, and IKK ${alpha}$ . A stimulatory and dose-dependent positive effect is only observed for IKK ${alpha}$ . Data are derived from three independent experiments and are represented as means + standard deviations.

To reveal the impact of the TIR adapter protein MyD88, the ubiquitinligase TRAF6, and the kinases involved in the TLR7/9 pathway,the mIRF7-expressing plasmid was used at low concentrations,to yield an approximately one- to fivefold induction of FL afterexpression of IRF7 alone. Cotransfection of increasing amountsof the ubiquitous TRAF6 had only weak stimulating effects (Fig.1B and data not shown); however, additional expression of MyD88greatly increased the induction of IFN ${alpha}$ 4-Luc in a dose-dependentmanner.

Both IRAK1 and IRAK4 have been described as kinases essentialfor TLR7/9-mediated IFN induction. Unexpectedly, however, additionalexpression of IRAK1 showed a substantial and dose-dependentinhibitory effect (Fig. 1C). A splicing variant of IRAK1, IRAK1c,which has been reported to have an inhibitory effect on TLR7/9signaling (47), showed almost identical inhibition. In contrastto IRAK1, additional expression of IRAK4 was not inhibitory,but a clear stimulatory effect was not observed (Fig. 1D).

In striking contrast to IRAKs, overexpression of IKK ${alpha}$ stronglyenhanced the basal induction obtained by coexpression of IRF7,MyD88, and TRAF6, indicating that IKK ${alpha}$ is directly involved inIRF7 phosphorylation. A transfection cocktail containing plasmidsencoding IRF7, MyD88, TRAF6, and IKK ${alpha}$ in a ratio of 1:5:5:5 showedspecific induction of IFN ${alpha}$ 4 in different transfectable cell lines,including Huh7.5 and BSR-T7/5 cells which have defects in RIG-I-mediated TBK1-dependent IFN induction (see below). Yet, theamount of plasmid mix necessary for high and reliable inductionvaried in different cell lines from 100 to 600 ng in total (datanot shown).

Expression of MV-P gene products. In order to determine whether MV-P gene products are involvedin the observed inhibition of TLR7/9 signaling in MV-infectedpDC (48), we constructed cDNAs for individual expression ofMV-P and -V, as well as the C protein (Fig. 2), which is producedby ribosomal leaky scanning to a second ORF downstream of theP/V start codon (3). While C has been described as an infectivityfactor (15), its impact on the IFN response remains controversial(42, 53, 56). In case of all P- or V-expressing plasmids, thestart codon of the C ORF was changed by site-directed silentmutagenesis to prevent expression of C by ribosomal scanning.P- and C-expressing plasmids were directly derived from reversetranscription-PCR of P mRNA from MV Schwarz-infected Vero cells,and V cDNA was generated by insertion of a single G residueat the P mRNA editing site. In addition, expression vectorsfor distinct P or V domains were constructed: MV-PV_N, includingthe N-terminal domain common to P and V (aa 1 to 231); MV-P_C,comprising the P-specific C-terminal domain (aa 232 to 507);and MV-V_C, comprising the V-specific C-terminal domain (aa 232to 299). As observed in Western blot experiments with P-, V-,and C-specific antisera, proteins of the expected specificityand size were expressed from transfected pCR3 vector plasmidsin 293T cells (not shown). In addition to the authentic proteins,constructs with N-terminal Ig, Flag, or His₆ tags were generated.

View larger version (15K):
[in this window]
[in a new window]

FIG. 2. MV-P gene products and cDNA constructs. The P gene of MV is located at the second position of the 16-kb MV negative-sense ssRNA [(–)ssRNA] genome. The P mRNA consists of 1,685 bases; insertion of an additional guanosine between bases 751 and 752 by RNA editing gives rise to the V mRNA. V and P proteins share a common N-terminal protein sequence (PV_N, aa 1 to 231) but have unique C termini (P_C, aa 232 to 507; V_C, aa 232 to 299). cDNAs encoding authentic or tagged P, V, PV_N, P_C, and V_C were constructed by cloning into different vectors for eukaryotic or prokaryotic expression. Expression of the C protein, which is encoded in an alternative ORF, was abolished in the P/V cDNA constructs by site-directed mutagenesis (for details see Materials and Methods) or was expressed from a separate cDNA.

MV-V protein inhibits IKK ${alpha}$ -dependent, but not TBK1-dependent, IFN- ${alpha}$ induction. After having established a suitable tool for the analysis ofIFN- ${alpha}$ induction by the MyD88/IKK ${alpha}$ -dependent signaling cascade,we examined the ability of MV proteins to interfere. Experimentswere carried out with Huh7.5 cells, as this cell line has adefect in RIG-I signaling (54), thereby minimizing TBK1/IKK ${varepsilon}$ -mediatedIFN induction. MV-V, MV-P, and the P protein of rabies virus(RV-P), which counteracts TBK1-mediated activation of IRF3 andIRF7, were coexpressed with the stimulating protein mixturedescribed above. In contrast to MV-P and RV-P proteins, MV-Vhad a substantial and dose-dependent inhibitory effect on theinduction of both IFN ${alpha}$ 4 and IFN ${alpha}$ 6 promoters (Fig. 3A and B). Inparallel experiments, the ability of the viral proteins to counteractTBK1-mediated induction of IFN promoters was addressed. To thisend, TBK1 was overexpressed to induce p55C1B (IRF3)-driven FL(Fig. 3C). While RV-P efficiently blocked expression of FL activity,neither of the MV proteins had inhibitory effects. Thus, MV-Vprotein specifically targets activation of IRF by the TLR7/9-and MyD88-dependent signal cascade, which involves IKK ${alpha}$ , butis ineffective in preventing the classical IFN-inducing pathwayinvolving TBK1 and the related IKK ${varepsilon}$ .

View larger version (24K):
[in this window]
[in a new window]

FIG. 3. MV-V protein inhibits MyD88-dependent induction of IFN- ${alpha}$ promoters. (A and B) Induction of IFNa4 (A) and IFNa6 (B) promoters by IRF7 (10 ng) and MyD88, TRAF6, and IKK ${alpha}$ (50 ng each) is inhibited by cotransfection of MV-V (250, 500, and 750 ng) in a dose-dependent manner, in contrast to MV-P and RV-P. (C) Induction of the p55C1B part of the IFN-β promoter by overexpression of TBK1 (150 ng of plasmid) is antagonized by expression of RV-P, but not by MV-V or MV-P. Data are derived from three independent experiments and are represented as means + standard deviations.

MV-V binds to IKK ${alpha}$ and IRF7. In order to identify the molecular targets of MV-V protein inthe TLR7/9-dependent IFN induction pathway, coprecipitationexperiments were performed. In a first trial, interaction ofMV proteins with the pathway-specific kinase IKK ${alpha}$ and its homologueswas addressed. Extracts from 293T cells coexpressing Ig-taggedMV proteins and Flag-tagged versions of IKK ${alpha}$ , IKKβ, TBK1,and IKK ${varepsilon}$ were purified by protein A-conjugated Sepharose beads.Indeed, IKK ${alpha}$ specifically copurified with Ig-MV-V, but not with-MV-P, or -MV-C (Fig. 4A). In a similar experiment, the interactionof MV proteins with IRF3 and IRF7 was assessed. Fl-IRF7 wascopurified with Ig-MV-V, but not with P or C proteins (Fig.4B), while Fl-IRF3 did not reveal interactions with either ofthe viral proteins.

View larger version (69K):
[in this window]
[in a new window]

FIG. 4. Interaction of MV-V with IKK ${alpha}$ and IRF7. (A and B) pIg-MV-P, -MV-V, and -MV-C or empty vector (pIg-e.v.) was cotransfected with pFl-IKK ${alpha}$ , -IKKβ, -TBK1, -IKK ${varepsilon}$ , -IRF7, or -IRF3 in 293T cells as indicated. Cells were lysed 24 h posttransfection under native conditions, and Ig-tagged proteins were pulled down with protein A-conjugated Sepharose beads and subjected to Western blot analysis. MV-V coprecipitated (co-IP) IKK ${alpha}$ , but not IKKβ, TBK1, or IKK ${varepsilon}$ (A), and in addition, IRF7, but not IRF3 (B). Precipitation of any of the kinases or transcription factors by MV-P or MV-C was not detected. (C and D) Native cell lysates of transfected 293T cells were subjected to anti-Flag affinity gel purification and analyzed by Western blotting. Flag-tagged IKK ${alpha}$ , IRF7, TBK1, and IRF3 were efficiently pulled down (D). Only MV-V was coprecipitated by IKK ${alpha}$ and IRF7, but not with TBK1 or IRF3 (C).

To confirm the apparently highly specific interactions, complementarypull-down experiments with Fl-IKK ${alpha}$ , -IRF7, -TBK1, and -IRF3 wereperformed. The proteins were purified from cell extracts withanti-Flag M2 affinity gel (Fig. 4D) and analyzed for coprecipitationof authentic, untagged MV-V, -P, and -C proteins. As revealedby Western blot experiments with antibodies specific for MVproteins, both Fl-IKK ${alpha}$ and Fl-IRF7 efficiently pulled down MV-Vprotein (Fig. 4C). For TBK1, a faint signal similar to the emptyvector control was observed. Apart from IKK ${alpha}$ and IRF7, no interactionsof MV-V, -P, or -C protein with other components of the signalingcomplex such as MyD88 or TRAF6 were indicated by comparableprecipitation experiments (data not shown). In summary, thestrong physical interaction of MV-V with IKK ${alpha}$ and IRF7, but notTBK1 and IRF3, was in line with the observed specificity ofblocking TLR9/MyD88-mediated IFN induction.

The C-terminal domain of V is sufficient for interaction with IKK ${alpha}$ and IRF7. As MV-V and -P proteins share an identical N-terminal domain(PV_N), the unique MV-V C-terminal domain (V_C) was assumed tobe key for binding to IKK ${alpha}$ and IRF7. The roles of the distinctprotein domains were therefore analyzed in protein A-Sepharosepull-down experiments, using Ig-tagged MV-PV_N, -P_C, and -V_Cconstructs along with the full-length proteins. In fact, Ig-MV-V_Cwas found sufficient for interaction with IKK ${alpha}$ . In contrast toIg-MV-PV_N or Ig-MV-P_C, Ig-MV-V_C very efficiently coprecipitatedIKK ${alpha}$ , while an interaction with TBK1 was not apparent (Fig. 5A).Similarly, Ig-MV-V_C pulled down Fl-IRF7 effectively (Fig. 5B).In reciprocal experiments using the anti-Flag M2 affinity pull-downsystem, Fl-IKK ${alpha}$ and Fl-IRF7 coprecipitated only Ig-MV-V_C butnot -PV_N or -P_C (Fig. 5C). In these experiments, a residualinteraction of Fl-IRF3 with V_C but also P_C could not be excluded(Fig. 5C). In summary, the 68-aa C terminus of MV-V is sufficientto autonomously and strongly interact with both IKK ${alpha}$ and IRF7.

View larger version (36K):
[in this window]
[in a new window]

FIG. 5. V_C mediates interaction with IKK ${alpha}$ and IRF7. (A and B) The indicated plasmids or empty vector (e.v.) was cotransfected with pFl-IKK ${alpha}$ , -TBK1, -IRF7, or -IRF3 into 293T cells. Ig-tagged proteins were pulled down under native conditions and analyzed by Western blotting for interaction partners. Full-length Ig-MV-V as well as Ig-V_C was identified to efficiently bind IKK ${alpha}$ , but not TBK1 (A). In addition, IRF7, but not IRF3, was precipitated by Ig-MV-V_C as efficiently as by full-length Ig-MV-V (B). (C) Native cell lysates of transfected 293T cells were subjected to anti-Flag affinity gel purification and analyzed by Western blotting for interaction of Fl-IKK ${alpha}$ , -IRF7, -TBK1, or -IRF3 with Ig-MV-PV_N, -MV-P_C, or -MV-V_C. Ig-MV-V_C was coprecipitated efficiently by both IKK ${alpha}$ and IRF7. Ig-MV-PV_N and Ig-MV-P_C did not show interaction with any of the tested proteins. (D) Luciferase reporter gene assay using overexpression of IRF7, MyD88, TRAF6, and IKK ${alpha}$ for induction of IFN ${alpha}$ 6-Luc in 293T cells. In contrast to full-length MV-V, which inhibits induction of the IFN ${alpha}$ 6 promoter in a dose-dependent manner (250, 500, and 750 ng), Ig-MV-V_C or MV-PV_N was ineffective. Data are derived from three independent experiments and are represented as means + standard deviations.

Notably, however, in spite of effective binding to IKK ${alpha}$ and IRF7,overexpression of Ig-MV-V_C did not inhibit stimulation of theIFN ${alpha}$ 6 promoter, in contrast to full-length Ig-MV-V (Fig. 5D).Thus, while the MV-V C terminus is required and sufficient tobind IKK ${alpha}$ and IRF7, the presence of the N terminus in the full-lengthprotein appears to be required in addition for inhibition ofIRF7 transcriptional activity.

IRF7 is inhibited independent of phosphorylation. Having identified IKK ${alpha}$ and IRF7 as direct targets of MV-V, weaddressed the question of at which step IRF7 activity is blocked.We therefore analyzed induction of IFN ${alpha}$ 6-Luc by overexpressionof IRF7, or of IRF7-2D, a constitutively active phosphomimeticIRF7 carrying S477D and S479D mutations (38). A dose-dependentinhibition of FL activity by MV-V was observed in both cases,although the inhibitory effect on IRF7-2D was less pronounced(Fig. 6B and C). The interaction with IRF7-2D was corroboratedby coprecipitation of IRF7-2D with both MV-V and the Ig-MV-V_Cfragment, while IRF3-5D, a constitutively active form of IRF3,was not coprecipitated (Fig. 6D). These results indicated thatthe interaction of MV-V with IRF7 is independent of the phosphorylationstatus of IRF7 and that IRF7 may be targeted prior to and postphosphorylationby IKK ${alpha}$ .

View larger version (38K):
[in this window]
[in a new window]

FIG. 6. MV-V is able to bind and inhibit activated IRF7. (A to C) Induction of IFN ${alpha}$ 6 promoter was stimulated in Huh7.5 cells by expression of IRF7 (10 ng plasmid) and MyD88, TRAF6, and IKK ${alpha}$ (50 ng each) (A) or by individual expression of IRF7 (100 ng) (B) or constitutively active IRF7-2D (100 ng) (C). Cotransfection of increasing amounts of MV-V (250, 500, 750 ng) revealed a dose-dependent inhibition in all experiments. (D) Plasmids encoding Ig-tagged MV-P, MV-V, MV-PV_N, MV-P_C, and MV-V_C or empty vector were cotransfected with phosphomimetic Fl-IRF7-2D, and Fl-IRF3-5D into 293T cells. Full-length Ig-MV-V as well as Ig-V_C was identified to bind IRF7, but not IRF3. Note that precipitated protein bands representing Ig-MV-V, -PV_N, and -P_C appear in the coimmunoprecipitation (Co-IP) figure (left panel) as well.

MV-V acts as a decoy substrate for IKK ${alpha}$ and blocks phosphorylation of IRF7. The binding of MV-V to IKK ${alpha}$ and IRF7 suggested the possibilitythat phosphorylation of IRF7 by IKK ${alpha}$ is hampered. To addressthis hypothesis, bacterial expression vectors were constructedand His-MV-V, His-MV-P, and His-IRF7 were expressed in Rosetta(DE3) cells. Proteins purified under native conditions by Ni-NTAcolumn purification were subjected to in vitro kinase assayswith commercial recombinant His-IKK ${alpha}$ and [ ${gamma}$ -³²P]ATP. In the presenceof constant and equal amounts of His-IRF7 and His-IKK ${alpha}$ and increasingamounts of His-MV-V, autoradiography revealed effective labelingof MV-V, identifying the MV-V protein as an excellent substratefor IKK ${alpha}$ (Fig. 7A). Moreover, ³²P labeling of IRF7 was diminishedwith increasing amounts of MV-V protein, suggesting successfulcompetition by MV-V protein.

View larger version (59K):
[in this window]
[in a new window]

FIG. 7. MV-V is a substrate of IKK ${alpha}$ and competes with IRF7 phosphorylation. His-tagged IRF7, MV-V, and MV-P were expressed in prokaryotic cells and purified by Ni-NTA affinity chromatography under native conditions. (A and B) Equal amounts of IRF7 (500 ng/reaction) and increasing amounts of MV-V (0 to 1,600 pmol per reaction) were subjected to an in vitro kinase assay together with commercial His-IKK ${alpha}$ (100 ng/reaction) and [ ${gamma}$ -³²P]ATP. Probes were subjected to Western blot analysis after incubation at indicated time points. Phosphorylation of proteins was detected by autoradiography, while total protein amounts were determined by Western blotting (WB). (A) MV-V is a substrate for efficient phosphorylation by IKK ${alpha}$ in vitro. Increasing amounts of MV-V reduce levels of phospho-IRF7, while total protein levels are equal in all lanes. ${alpha}$ -His, anti-His. (B) Quantification of phospho-IRF7 over time with dependence on increasing amounts of MV-V. IRF7 phosphorylation is completely abolished in the presence of large amounts of MV-V (800 and 1,600 pmol), while smaller amounts of MV-V (200 and 400 pmol) delay IRF7 phosphorylation. (C and D) Five hundred nanograms of His-IRF7 (C) or 100 ng of GST-I ${kappa}$ B- ${alpha}$ (D) was subjected to an in vitro kinase assay in either the absence (lanes 1) or presence (lanes 2 to 4) of 100 ng of His-IKK ${alpha}$ and 100 pmol of His-MV-V (lanes 3) or His-MV-P (lanes 4). Reactions were stopped after indicated time points and subjected to Western blot analysis. (E and F) Quantification of phospho-IRF7 (E) or pI ${kappa}$ B- ${alpha}$ (F) reveals specificity of MV-V. Phosphorylation of IRF7 is inhibited only by MV-V, but not MV-P. Phosphorylation of I ${kappa}$ B- ${alpha}$ is not inhibited by either viral protein. (G) Reduction of activated IRF7 in living cells. Flag-tagged IKK ${alpha}$ , IRF7, and MV-V were pulled down from 293T cells transfected with the indicated plasmids at 24 h posttransfection and analyzed by Western blotting using anti-Flag M2 antibody. A band representing activated IRF7 (marked by a star) appeared only after coexpression of IKK ${alpha}$ and IRF7. A significant reduction of this band was observed in the presence of MV-V.

Quantification of phosphorylated IRF7 revealed a dose-dependentreduction of IRF7 phosphorylation at lower doses of MV-V (200and 400 pmol/reaction), although substantial phosphorylationof IRF7 after a longer incubation time was accomplished. Higherdoses (800 and 1,600 pmol/reaction) resulted in an almost completeinhibition of IRF7 phosphorylation (Fig. 7B). In contrast, purifiedHis-MV-P was not able to interfere with phosphorylation of IRF7,although it was also phosphorylated by IKK ${alpha}$ (Fig. 7C and E).In contrast to IRF7, phosphorylation of another IKK ${alpha}$ substrate,I ${kappa}$ B- ${alpha}$ , was not inhibited by either MV-V or MV-P. These resultsindicate that MV-V in vitro acts as a substrate for IKK ${alpha}$ whichis able to specifically compete with phosphorylation of IRF7.

To verify inhibition of IRF7 phosphorylation in living cells,Fl-IKK ${alpha}$ , Fl-IRF7, and Fl-MV-V were expressed in different combinationsin 293T cells and pull-down assays were performed using an anti-FlagM2 affinity gel. After coexpression of IRF7 and IKK ${alpha}$ , an extraband migrating slower appeared (Fig. 7G) representing activatedphospho-IRF7 as it was not observed in cells expressing IRF7only. The intensity of this band was clearly decreased in thepresence of MV-V, while the overall levels of IRF7 were comparable.In summary, the data provide evidence for direct suppressionof IRF7 activation by IKK ${alpha}$ , which is operational only in theTLR7/9-MyD88-dependent IFN induction.

DISCUSSION

Top

DISCUSSION

Based on its immunosuppressive features and a Th2-biased immuneresponse (41, 50), we have recently assessed MV for potentialeffects on pDC. MV was identified to potently inhibit IFN inductionin human pDC in vitro in response to both virus infection andexogenous TLR7 and -9 agonists, including R848 and CpG oligodeoxynucleotide(48). Here, we have identified the MV-V protein as instrumentalin blocking MyD88-dependent IFN ${alpha}$ signaling and have observedan unanticipated mechanism involving both kinase (IKK ${alpha}$ ) and substrate(IRF7) as binding targets.

Canonical IFN induction following stimulation of the almostubiquitous cytosolic RNA helicases RIG-I and MDA5, or of TLR3and TLR4, critically involves the kinases TBK1 and IKK ${varepsilon}$ to activateboth IRF3 and IRF7. In contrast, MyD88-dependent IFN inductionis independent of TBK1/IKK ${varepsilon}$ and leads to activation of exclusivelyIRF7 in a spatiotemporally controlled signaling complex of specializedimmune cells equipped with TLR7/8 and -9, such as pDC (30).Here, we exploited transient expression in cell lines of theinvolved signaling components to mimic MyD88-dependent IRF7activation and to allow discrimination from TBK1-mediated activation.Specifically, RV-P as an established potent inhibitor of TBK1and IKK ${varepsilon}$ -mediated phosphorylation of IRF3 and IRF7 (4, 6) wasnot able to interfere with induction of IFN ${alpha}$ 4 and IFN ${alpha}$ 6 promotersby the "MyD88 mix," in contrast to MV-V, while V was not ableto block TBK1-mediated IFN induction. The observed specificityof induction also allowed assignment of a critical and dose-dependentrole to IKK ${alpha}$ as the kinase phosphorylating IRF7, thus corroboratingthe recently described role of IKK ${alpha}$ in TLR7/9-induced IFN ${alpha}$ production(29). In contrast, overexpression of IRAK4 or IRAK1, assumedto be responsible for MyD88-dependent IRF7 phosphorylation (58,59), had no effect or inhibitory effects in 293T or Huh7.5 cells.However, since pDC from IRAK1-deficient mice (59) and humans(60) were found to be severely deficient in the activation ofIRF7 and in the production of IFN- ${alpha}$ , an essential indirect orregulatory role of this kinase in pDC is suggested.

Intriguingly, both IKK ${alpha}$ and IRF7 were found to be high-affinitybinding partners of the MV-V protein, but not of MV-P or -C,which are also implicated in MV IFN escape. Significant interactionof MV-V with the closely related kinases IKKβ, TBK1, andIKK ${varepsilon}$ or with IRF3 could not be demonstrated, although in individualexperiments a residual affinity to TBK1 (Fig. 4C) and IRF3 (Fig.5C) could not be excluded. MV-V is a multifunctional proteincontaining an N-terminal 231-residue domain that is shared withthe P protein (PV_N) and a distinct C-terminal domain of 68 aa(V_C) that is cysteine rich and which is conserved among paramyxoviruses.As the MV-P protein failed both in inhibiting MyD88-dependentIFN- ${alpha}$ promoter activation and in binding to IRF7 and IKK ${alpha}$ , a crucialrole of V_C was immediately obvious. Actually, an Ig-V_C fusionprotein was sufficient for binding to both IRF7 and IKK ${alpha}$ yetwas not active in preventing IFN promoter induction. This suggeststhat V_C is functioning primarily as a targeting module directingfull-length V protein to IKK ${alpha}$ and IRF7 and indicates a contributionof the common N terminus in the mechanism of inhibition, eitherby serving as a decoy substrate for IKK ${alpha}$ or by more efficientlyretaining IRF7 in the cytosol.

As indicated by in vitro kinase experiments, MV-V is a bettersubstrate for IKK ${alpha}$ than IRF7 and can successfully compete withIRF7 phosphorylation in vitro, although phosphorylation of IRF7ensues over time in the presence of V. MV-P was not able toinhibit IRF7 phosphorylation, though it was also used as a substratefor IKK ${alpha}$ in vitro. Since V binds IKK ${alpha}$ and IRF7 independently fromeach other, this competing effect can be due to a higher affinityand phosphorylation of V by IKK ${alpha}$ or to impaired recruitment ofIRF7 to IKK ${alpha}$ . Indeed, in transfected cells, the ratio of phosphorylatedversus nonphosphorylated IRF7 was found significantly reducedin the presence of MV-V, suggesting an important contributionof these mechanisms to inhibition of IFN induction. Moreover,it is suggested that MV-V may bind in addition to activatedIRF7, as indicated by coprecipitation and inhibition of thetranscriptional activity of the phosphomimetic IRF7-2D. Allof the activities observed are suitable to prevent dimerizationand/or import of IRF7 upon TLR7/9 activation into the nucleus.

As for other paramyxovirus V proteins, MV-V, but not MV-P, bindsto MDA5 and prevents MDA5 downstream signaling to canonicalIFN induction (1, 11). Though rhabdoviruses and paramyxovirusespredominantly activate RIG-I through their 5'-triphosphate leaderRNAs (27, 46), a cell-type-dependent contribution by MDA5 maybe critical (62). In addition, MV-V counteracts JAK/STAT signaling(7, 43, 44, 55), although the P protein is active in this respectas well (17). In addition, MV-V, but not -P, was reported tocopurify with a variety of proteins, including STAT1, STAT2,IRF9, and STAT3 (12, 44), and to block STAT2 phosphorylation(55) and activation of the kinase JAK1 (61). Altogether, theseand the present observations prompt the idea of the V_C domainas an autonomous and important immune targeting module withmultiple distinct destinations.

While it is exciting to see that Paramyxoviridae use their Vproteins as a universal tool to simultaneously counteract multiplemajor pathways of the innate immunity, it is intriguing to seehow this tool is adapted by evolution to fit the specific virusneed. The uniqueness of the MV-V protein in targeting TLR-MyD88-dependentIFN induction in pDC is emphasized by very recent complementarywork. While this article was in preparation, Lu et al. (40)described the inhibition of TBK1/IKK ${varepsilon}$ -mediated IRF3 activationby the V proteins of members of the Rubulavirus genus, includingmumps virus, human parainfluenza virus 2, and canine parainfluenzavirus 5 (previously known as simian virus 5). A direct interactionbetween V and TBK1/IKK ${varepsilon}$ and phosphorylation of V was observed.In contrast, MV-V failed to block TBK1/IKK ${varepsilon}$ activity (40), supportingour observation of specific targeting of IKK ${alpha}$ . Thus, while rubulavirusesmay have the potential to inhibit all but MyD88-dependent IFNinduction, the hematopoietic MV may have evolved to specificallytarget IKK ${alpha}$ , probably at the expense of targeting TBK1. Moreover,targeting of IRF7 is a completely novel feature of the MV-Vprotein.

The ability to simultaneously target IKK ${alpha}$ and IRF7 may explainhow MV can blindfold pDC and make hosts more permissive to otherpathogens. Activation of pDC by a variety of pathogens not onlysets off antiviral mechanisms of the type I IFN network butprofoundly shapes the host adaptive immune system by promotingcross-presentation and Th1 immune responses (31). Although additionalspecific mechanisms to counteract adaptive immunity are employedby MV, such as changes in lymphocyte number and function andantigen presentation (51, 52), contact-mediated inhibition ofT-cell proliferation (49), and shifts in cytokine responses,particularly of IL-10 and IL-12 (20, 21, 41), it is assumedthat the early prevention of pDC function by MV-V protein setsthe stage for several of these specific immunosuppressive mechanismsto be more effectual.

A recent study involving V-deficient MV in a rhesus monkey modelrevealed reduced infectivity of peripheral blood mononuclearcells and lymphatic organs and impaired capacity to controltype I IFN and inflammatory cytokines compared to wild-typeMV (16). Although pDC are capable of producing IFN independentlyof the positive IFN feedback loop (2, 32), the JAK/STAT- andMDA5-inhibitory functions of MV-V may contribute to lower systemicIFN levels (26, 57). The results provided here open the wayfor mutagenesis experiments to generate MV with specific defectsin blocking either IKK ${alpha}$ , JAK/STAT, or MDA5 signaling, in orderto reasonably appreciate the contribution of these individualfunctions to MV immune biology in vivo. Such studies will notonly lead to recombinant vaccine viruses with abolished or reducedcapacity to undermine the host immune response but also mayhelp to develop tools to specifically interfere with immunopathologicalTLR signaling.

ACKNOWLEDGMENTS

We thank N. Hagendorf for perfect technical assistance and L.Fragnet for critical reading of the manuscript. MV-P, -V, and-C antisera were kindly provided by R. Cattaneo, D. Gerlier,K. Takeuchi, and S. Schneider-Schaulies, Huh7.5 cells were providedby C. Rice, and cDNAs were provided by S. Akira, J. Hiscott,T. Fujita, K. Ruckdeschel, and A. Kieser.

This work represents part of the Ph.D. thesis of C.K.P. andwas supported by the Deutsche Forschungsgemeinschaft throughGraKo 1202 "Oligonucleotides in cell biology and therapy" andSFB 455 "Viral functions and immune modulation."

FOOTNOTES

* Corresponding author. Mailing address: Max von Pettenkofer-Institute & Gene Center, Feodor-Lynen-Str. 25, D-81377 Munich, Germany. Phone: 49 89 2180 76851. Fax: 49 89 2180 76899. E-mail: conzelma{at}lmb.uni-muenchen.de

Published ahead of print on 15 October 2008.

REFERENCES

Top