Ebola Virus VP24 Binds Karyopherin {alpha}1 and Blocks STAT1 Nuclear Accumulation

Ebola virus (EBOV) infection blocks cellular production of alpha/betainterferon (IFN- ${alpha}$ /ß) and the ability of cells to respondto IFN- ${alpha}$ /ß or IFN- ${gamma}$ . The EBOV VP35 protein has previouslybeen identified as an EBOV-encoded inhibitor of IFN- ${alpha}$ /ßproduction. However, the mechanism by which EBOV infection inhibitsresponses to IFNs has not previously been defined. Here we demonstratethat the EBOV VP24 protein functions as an inhibitor of IFN- ${alpha}$ /ßand IFN- ${gamma}$ signaling. Expression of VP24 results in an inhibitionof IFN-induced gene expression and an inability of IFNs to inducean antiviral state. The VP24-mediated inhibition of cellularresponses to IFNs correlates with the impaired nuclear accumulationof tyrosine-phosphorylated STAT1 (PY-STAT1), a key step in bothIFN- ${alpha}$ /ß and IFN- ${gamma}$ signaling. Consistent with this proposedfunction for VP24, infection of cells with EBOV also confersa block to the IFN-induced nuclear accumulation of PY-STAT1.Further, VP24 is found to specifically interact with karyopherin ${alpha}$ 1, the nuclear localization signal receptor for PY-STAT1, butnot with karyopherin ${alpha}$ 2, ${alpha}$ 3, or ${alpha}$ 4. Overexpression of VP24 resultsin a loss of karyopherin ${alpha}$ 1-PY-STAT1 interaction, indicatingthat the VP24-karyopherin ${alpha}$ 1 interaction contributes to the blockto IFN signaling. These data suggest that VP24 is likely tobe an important virulence determinant that allows EBOV to evadethe antiviral effects of IFNs.

INTRODUCTION

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Introduction

The filoviruses, Ebola virus (EBOV) and Marburg virus, causeperiodic outbreaks of severe hemorrhagic fever in humans. InEBOV outbreaks consisting of more than 10 reported cases, mortalityrates have ranged from 40 to 90% (41), and Marburg virus outbreakshave had reported case fatality rates ranging from 25 to 80%(13). This extreme virulence has made Ebola and Marburg virusesof concern both as naturally emerging pathogens and as potentialbioweapons (41).

The molecular mechanisms contributing to the severe pathogenesisof filovirus infection are poorly understood. Several potentialmechanisms contributing to EBOV virulence have been reviewed(41). These include cytotoxicity of the viral glycoprotein,the production of proinflammatory cytokines, and the dysregulationof the coagulation cascade due to the production of tissue factor(14, 20, 21, 62, 64). Infection also appears to induce a generalimmune suppression (11, 53). Possible mechanisms contributingto this suppression include inhibition of dendritic cell activationand an induction of lymphocyte apoptosis (2, 8, 18, 22, 43).Each of these pathogenic processes likely occurs as a resultof the active replication of the virus. Thus, the ability ofthe virus to counteract early antiviral responses, includingthose of the host's interferon system, likely plays an importantrole in EBOV virulence (41).

EBOV encodes mechanisms to counteract the host interferon (IFN)response by blocking both production of IFN- ${alpha}$ /ß andcellular responses to IFN- ${alpha}$ /ß or - ${gamma}$ treatment (6, 24,26, 27). We previously demonstrated that the EBOV VP35 proteinsuppresses IFN- ${alpha}$ /ß production by inhibiting the activationof interferon regulatory factor 3 (IRF-3) (5, 7, 51), and subsequentstudies confirm that VP35 exerts this function (8, 28). However,the manner in which EBOV blocks signaling from the IFN- ${alpha}$ /ßor - ${gamma}$ receptor has remained incompletely defined.

IFN- ${alpha}$ /ß, a family of structurally related proteins,and IFN- ${gamma}$ bind to two distinct receptors but activate similarsignaling pathways (reviewed in reference 38). For both pathways,ligand binding activates receptor-associated Jak family tyrosinekinases. These undergo auto- and transphosphorylation and phosphorylatethe cytoplasmic domains of the receptor subunits. The receptor-associatedphosphotyrosine residues then serve as docking sites for theSH2 domains of STAT proteins. The receptor-associated STATsthen undergo tyrosine-phosphorylation and form homo- or heterodimersvia reciprocal SH2 domain-phosphotyrosine interactions. Signalingfrom the IFN- ${alpha}$ /ß receptor results predominately inthe formation of STAT1:STAT2 heterodimers which additionallyinteract with IRF-9. IFN- ${gamma}$ signaling results predominately inthe formation of STAT1:STAT1 homodimers. Upon dimerization,the STAT1:STAT2 heterodimer or the STAT1:STAT1 homodimer interactswith a specific member of the karyopherin ${alpha}$ (also known as importin ${alpha}$ ) family of nuclear localization signal (NLS) receptors, karyopherin ${alpha}$ 1 (importin ${alpha}$ 5) (45, 48, 55). This interaction with karyopherin ${alpha}$ 1 mediates the nuclear accumulation of these STAT1-containingcomplexes (45, 48, 55). The consequence of the activation andnuclear accumulation of these complexes is the specific transcriptionalregulation of numerous genes, some of which have antiviral properties(39).

In the present study, we demonstrate that the Zaire EBOV VP24protein, a minor viral structural protein previously implicatedin viral nucleocapsid formation (31, 63), viral budding or assembly(3, 25), and host range determination (61), is capable of blockingboth IFN- ${alpha}$ /ß and IFN- ${gamma}$ signaling. Mechanistically, wefind that VP24 prevents the nuclear accumulation of tyrosine-phosphorylatedSTAT1 (PY-STAT1); moreover, we provide evidence that an interactionbetween VP24 and karyopherin ${alpha}$ 1 mediates this inhibition. Theresult is a subversion of the antiviral effects of IFNs. Consistentwith the role of VP24 as an EBOV-encoded antagonist of IFN signalingpathways, we find that EBOV infection also imposes a block tothe nuclear accumulation of PY-STAT1 following IFN treatment.Subversion of the IFN signaling pathways likely promotes EBOVpropagation in vivo and contributes to viral pathogenesis. Strategiesthat target this function of VP24 may enhance the efficacy ofIFNs toward EBOV.

MATERIALS AND METHODS

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Materials and Methods

Cells and viruses. 293T cells, 293 cells, and Vero cells were maintained in Dulbecco'smodified Eagle's medium (DMEM) supplemented with 10% fetal bovineserum (FBS). Sendai virus strain Cantell was grown in 10-day-oldembryonated chicken eggs at 37°C for 48 h. Zaire EBOV wasgrown and EBOV infections were performed in Vero E6 cells atthe Centers for Disease Control and Prevention under biosafetylevel 4 (BSL-4) containment. For analysis by immunofluorescencemicroscopy, Vero cells were plated onto 12-mm-diameter glasscoverslips and infected at a multiplicity of infection (MOI)of 0.5. For analysis of tyrosine-phosphorylated STAT1 by Westernblotting, cells were cultured in a 24-well plate and infectedat an MOI of 1.0.

Reporter gene assays. Vero cells were transfected using Lipofectamine 2000 (Invitrogen,Carlsbad, CA) as outlined in the manufacturer's protocol. Cellmonoloayers, 90 to 95% confluent in six-well plates, were transfectedwith 1.5 µg of an ISG54 promoter chloramphenicol acetyltransferase(CAT) reporter construct (pHISG54-CAT) or of an IRF-1 gamma-activatedsequence (GAS) element-driven luciferase reporter construct(35), 1 µg of a constitutively expressing luciferase reporterconstruct (pCAGGS-luc), and 2.5 µg of the relevant expressionplasmid. Twenty-four hours posttransfection, cells were washedand maintained in Dulbecco's modified Eagle medium containing0.3% bovine serum albumin, with or without (mock-treated control)1,000 U/ml of human IFN-ß or 1,000 U/ml of human IFN- ${gamma}$ (as indicated) (Calbiochem, San Diego, CA). Twenty-four hourspost-IFN treatment, cells were harvested and analyzed for CATand luciferase activities. The CAT activity was quantified byusing a PhosphorImager and normalized to the luciferase activity.

Western blots and coimmunoprecipitations. To detect STAT1 levels, 293T cells were transfected as describedabove with 10 ng of a human IRF-9 expression plasmid (pCAGGS-hIRF-9)and 2.5 µg of the expression plasmids indicated in thetext. We included pCAGGS-hIRF-9 because these 293T cells donot efficiently respond to IFN-ß without overexpressionof IRF-9 (data not shown). Twenty-four hours posttransfection,the medium was replaced with DMEM, 0.3% bovine serum albumin(BSA), 1,000 U/ml human IFN-ß (Calbiochem). Eighteenhours post-IFN-ß addition, cells were harvested andlysed in extract buffer (50 mM Tris [pH 7.5], 280 mM NaCl, 0.5%Igepal, 0.2 mM EDTA, 2 mM EGTA, 10% glycerol, 1 mM dithiothreitol,1 mM sodium vanadate, and protease inhibitors [Complete; Roche]).Total cell extracts were analyzed by sodium dodecyl sulfate-polyacrylamidegel electrophoresis (SDS-PAGE), and the proteins were transferredto a polyvinylidene difluoride (PVDF) membrane and probed withrabbit polyclonal antibodies against human STAT1 (BD TransductionLaboratories) and ß-actin (Sigma). The Western blotswere developed using the Western Lightning ECL kit (Perkin-Elmer,Boston, MA) and Kodak BioMax film (Kodak, Rochester, NY).

To detect MxA in EBOV-infected Vero cells, cell lysates werefrozen and decontaminated by exposure to 5 million rads of gammaradiation. Aliquots of the protein lysates were then resolvedby SDS-PAGE and transferred to PVDF. The membrane was blockedin 5% milk and 0.2% Tween 20 in PBS (PBS-T) and then incubatedwith a mouse antibody raised against MxA diluted 1:500 (theantibody was generously provided by Georg Koch and Otto Haller,Department of Virology, University of Freiberg, Freiberg, Germany),and a mouse antibody raised against glyceraldehyde-3-phosphatedehydrogenase (GAPDH) (Abcam, Cambridge, United Kingdom). Afterrinsing with PBS-T, the blot was incubated with an alkalinephosphatase-conjugated goat antibody raised against mouse immunoglobulinG (IgG) (Rockland, Gilbertsville, PA) and visualized with ECFreagent and a Storm 860 PhosphorImager (Amersham Biosciences,Piscataway, NJ). To detect the presence of the EBOV proteinVP24, the membrane was incubated with a rabbit antibody raisedagainst VP24 (diluted 1:2,000), rinsed with PBS-T, and incubatedwith a horseradish peroxidase (HRP)-conjugated goat antibodyraised against rabbit IgG (Sigma, St. Louis, MO). The VP24 Westernblot was developed using the Western Lightning ECL kit (Perkin-Elmer,Boston, MA) and Kodak BioMax film (Kodak, Rochester, NY).

For coimmunoprecipitation experiments, 293T cells were transfectedwith 1 µg of expression plasmids unless otherwise indicated.Following a 24-h incubation, cells were washed in ice-cold PBSand lysed in 500 µl of extract buffer for 10 min on ice.For Fig. 6B and C, prior to lysis, the cells were mock treatedor treated with 1,000 U/ml human IFN-ß (Calbiochem)for 1 h as indicated. Extracts were centrifuged at 13,000 rpmfor 10 min at 4°C in a microcentrifuge, the supernatantwas collected, and 20 µl of 50% slurry of M2 (anti-FLAG)monoclonal antibody cross-linked to agarose beads (Sigma) wasadded and incubated for at least 1 h at 4°C with rotation.The M2-agarose beads were washed three times with extract bufferand boiled in SDS-PAGE sample buffer. For VP24 coimmunoprecipitationwith FLAG-karyopherin ${alpha}$ s, the immunoprecipitated material wasanalyzed by SDS-PAGE and immunoblotting with rabbit polyclonalantibody against FLAG (Sigma) or against VP24. Separately, blotswere probed with an anti-VP35 monoclonal antibody. For FLAG-karyopherin ${alpha}$ 1, STAT1-green fluorescent protein (GFP) and hemagglutinin (HA)-VP24coimmunoprecipitations, the immunoprecipitated material wasanalyzed by SDS-PAGE and immunoblotting with rabbit polyclonalantibody against PY-STAT1 (pY701; Cell Signaling Technology)or against STAT1 (BD Biosciences) where indicated. Additionally,immunoblotting was also performed with monoclonal anti-HA andanti-FLAG antibodies (Sigma) where indicated. Whole-cell extracts(1% of total material used for immunoprecipitation) were immunoblottedwith the same antibodies in parallel. The Western blots weredeveloped using the Western lightning ECL kit (Perkin-Elmer,Boston, MA) and Kodak BioMax film (Kodak, Rochester, NY).

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FIG. 6. VP24 interacts with karyopherin ${alpha}$ 1 and inhibits karopherin ${alpha}$ 1-phospho (Tyr 701)-STAT1 interaction. (A) Coimmunoprecipitation of VP24 with karyopherin ${alpha}$ 1. 293T cells were transfected with the indicated plasmids expressing VP24, VP35, or firefly luciferase (indicated by a hyphen) in the absence or presence of plasmids expressing FLAG-tagged karyopherin ${alpha}$ 1 (FLAG-K ${alpha}$ 1), ${alpha}$ 2 (FLAG-K ${alpha}$ 2), ${alpha}$ 3 (FLAG-K ${alpha}$ 3), or ${alpha}$ 4 (FLAG-K ${alpha}$ 4). Cell extracts were prepared 1 day posttransfection, and immunoprecipitations (IP) were performed with anti-FLAG monoclonal antibody M2 bound to agarose beads. After washing, immunoprecipitates were analyzed by Western blotting (WB) with polyclonal rabbit antisera recognizing FLAG and VP24 (top panel; 50% of total material was analyzed). Whole-cell extracts (WCE) (1% of total) were also analyzed by Western blotting for karyopherin expression (anti-FLAG antibody), VP24, or VP35, as indicated. (B) 293T cells were transfected with the indicated expression plasmids. Lanes 1 and 4, FLAG-karyopherin ${alpha}$ 1 and STAT1-GFP; lanes 2 and 5, FLAG-karyopherin ${alpha}$ 1 and HA-VP24; lanes 3 and 6, FLAG-karyopherin ${alpha}$ 1, STAT1-GFP, and HA-VP24. The cells were then mock treated or treated with 1,000 U/ml human IFN-ß and subsequently immunoprecipitated with anti-FLAG monoclonal antibody M2 bound to agarose beads (IP: FLAG). After washing, the immunoprecipitates were analyzed by Western blotting with a monoclonal antibody recognizing STAT1 (WB: STAT1), and monoclonal antibodies against FLAG (WB: FLAG) and HA (WB: HA) (top panel; 10% of total material analyzed). Whole-cell extracts (1% of total) were also analyzed similarly. (C) 293T cells were transfected with FLAG-karyopherin ${alpha}$ 1 (250 ng); STAT1-GFP (250 ng); or 0, 25, 250, 500, and 1,000 ng of HA-VP24 (lanes 1 to 5, respectively) expression plasmids. Lane 6 contains samples derived from cells transfected with STAT1-GFP plasmid but not with karyopherin ${alpha}$ 1 plasmid. The cells were then treated with 1,000 U/ml human IFN-ß and subsequently immunoprecipitated with anti-FLAG monoclonal antibody and analyzed by Western blotting with polyclonal rabbit antisera recognizing phosphorylated STAT1 and monoclonal antibodies against FLAG and HA (top panel, 10% of total material analyzed). Whole-cell extracts (1% of total) were also analyzed. Asterisks indicate the heavy chain of the anti-FLAG monoclonal M2 antibody used for the immunoprecipitation.

Measuring the antiviral state in cells. Vero cells were transfected by using LF2000 with 2.5 µgof the indicated expression plasmid. Twenty-four hours posttransfection,the cells were mock treated or treated with 1,000 U/ml of humanIFN-ß as described above. Twenty-four hours post-IFN-ßtreatment, the cells were infected with Newcastle disease virusexpressing GFP (NDV-GFP) (6.4 turkey red blood cell hemagglutinatingunits/ml) (50), and after 24 h of infection GFP was visualizedby fluorescence microscopy.

STAT1 and GFP-IRF-3 nuclear translocation. Vero cells were plated onto 12-mm-diameter glass coverslipsand transfected with empty vector (pCAGGS), pCAGGS-FLAG-VP24,or pCAGGS-FLAG-VP35 using Lipofectamine 2000 following the manufacturer'srecommended protocol. Twenty-four hours posttransfection, thecells were serum starved for 4 h and then either mock treatedor treated with 1,000 U/ml of human IFN-ß or humanIFN- ${gamma}$ for 30 min at 37°C. After rinsing three times withPBS containing 1 mM each of calcium chloride and magnesium chloride(PBS-CM), the cells were placed on ice and fixed with –20°Cmethanol for 10 min. After rehydrating in PBS-CM, the cellswere blocked in PBS-CM containing 4% normal goat serum, 1% BSA,and 0.075% saponin for 45 min at ambient temperature. The coverslipswere incubated with a mouse antibody raised against STAT1 (5µg/ml; BD Bioscience, Franklin Lakes, NJ) and a rabbitantibody raised against the FLAG epitope (4 µg/ml; Sigma,St. Louis, MO) in 1% BSA-Tris-buffered saline (TBS) for 1 h,followed by three washes of PBS. The coverslips were incubatedwith an Alexa 488-conjugated goat antibody raised against mouseIgG and an Alexa 594-conjugated antibody raised against rabbitIgG (0.5 µg/ml each; Molecular Probes, Eugene, OR) andHoechst 33342 (0.1 µg/ml; Molecular Probes, Eugene, OR)for 30 min. After rinsing, the coverslips were mounted on slidesand imaged on a Zeiss Axiophot 2 equipped with a Ratiga charge-coupleddevice (CCD) camera. Individual color channels were acquiredas 8-bit monochrome images and pseudocolored using ImageJ (NIH,Bethesda, MD). To quantify the number of cells expressing nuclearSTAT1, at least three independent fields (at least 36 cells)for each experimental condition were acquired. Cells that demonstratedcolocalization of Hoechst and STAT1 staining were consideredto have nuclear STAT1.

GFP-IRF-3 translocation assays were performed in Vero cellsfollowing a previously described procedure (5).

Detection of tyrosine-phosphorylated STAT1 in IFN-ß-treated Vero cells. (i) Immunofluorescence microscopy. Vero cells were plated on 12-mm-diameter glass coverslips andcultured in 10% FBS in DMEM. Before treatment with IFN-ß,cells were rinsed twice with Optimem medium (Invitrogen) andincubated in the absence of serum for 4 h. Human IFN-ßwas added (1,000 U/ml in DMEM), and the cells were culturedfor 30 min. The cells were then fixed and blocked as describedabove for STAT1 staining. The cells were rinsed three timeswith 1% BSA in TBS and incubated with a rabbit antibody raisedagainst a synthetic phosphopeptide (keyhole limpet hemocyanincoupled) corresponding to residues surrounding Tyr 701 of humanStat1 (0.2 µg/ml; Cell Signaling, Beverly, MA) and a mouseantibody raised against the FLAG epitope (4 µg/ml; Sigma,St. Louis MO) in 1% BSA-TBS for 1 h, followed by three washesof PBS. For cells infected with EBOV under BSL-4 conditions,coverslips were decontaminated at this stage by incubation with4% paraformaldehyde in PBS for 48 h before transferring themto a BSL-2 environment.

The coverslips were incubated with Alexa 594-conjugated goatantibodies raised against mouse IgG (0.5 µg/ml; MolecularProbes, Eugene, OR), Alexa 488-conjugated antibodies raisedagainst rabbit IgG (0.5 µg/ml each; Molecular Probes,Eugene, OR) and Hoechst 33342 (0.1 µg/ml; Molecular Probes,Eugene, OR) for 30 min. After rinsing, the coverslips were mountedon slides and imaged on a Zeiss Axiophot 2 equipped with a RatigaCCD camera. Individual color channels were acquired as 8-bitmonochrome images and pseudocolored using ImageJ (NIH, Bethesda,MD). To quantify the number of cells expressing nuclear PY-STAT1,four independent fields of Ebola virus-infected cells were acquired.Cells that demonstrated colocalization of Hoechst and STAT1staining were considered to have nuclear STAT1. Cells demonstratingstaining for the Ebola virus VP35 protein were considered tobe infected.

(ii) To detect the presence of tyrosine-phosphorylated STAT1in EBOV-infected Vero cells, extracts were prepared using thePierce NE-PER kit (Pierce, Rockford, IL) according to the manufacturer'srecommendation. The lysates were frozen and decontaminated with5 million rads of gamma radiation. Prior to analysis, the nuclearand cytoplasmic fractions were combined to produce a total lysate.The protein samples were resolved on a 10% polyacrylamide gelby SDS-PAGE and transferred to PVDF. After blocking in 5% nonfatmilk and 0.2% Tween 20 in TBS (TBS-T), the membrane was probedby incubation with a rabbit antibody raised against tyrosine-phosphorylatedSTAT1 (0.02 µg/ml; Cell Signaling, Beverly, MA) and arabbit antibody raised against GAPDH (Abcam, Cambridge, UnitedKingdom). After rinsing, the blot was incubated with an alkalinephosphatase-conjugated goat antibody raised against rabbit IgG(Rockland, Gilbertsville, PA) and visualized using using ECFreagent and a Storm 860 PhosphorImager (Amersham Biosciences,Piscataway, NJ).

RESULTS

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Results

EBOV VP24 inhibits induction of gene expression by IFN-ß and IFN- ${gamma}$ . In order to identify an EBOV protein(s) capable of inhibitingcellular responses to IFN treatment, cDNAs encoding individualEBOV proteins were screened for their ability to inhibit theIFN-ß-induced expression of an IFN-responsive, ISG54promoter-driven CAT reporter gene. Only the VP24 protein wasable to efficiently and reproducibly inhibit gene activationin this assay (data not shown). The ability of VP24 to inhibitIFN-ß signaling is demonstrated in Fig. 1A. In thisexperiment, Vero cells were cotransfected with the ISG54-CATreporter and an empty expression plasmid or expression plasmidsfor the Nipah virus W protein, a previously demonstrated inhibitorof IFN signaling (50, 56), FLAG-tagged VP24, an untagged VP24protein, or VP35, the EBOV protein previously implicated asan inhibitor of IFN- ${alpha}$ /ß production (5, 7) (Fig. 1A).An $~$ 30-fold induction in CAT activity was seen in IFN-ß-treatedsamples transfected with empty vector (as compared with an emptyvector-transfected, mock-treated sample). This activation wasinhibited in cells expressing either tagged or untagged VP24protein and in cells expressing Nipah W, whereas a differentEBOV protein, VP35, did not inhibit IFN-ß-inducedgene expression (Fig. 1A).

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FIG. 1. Ebola virus VP24 inhibits IFN-ß and - ${gamma}$ induced gene expression. (A) IFN-ß-induced reporter gene activation in Vero cells was measured. Cells were cotransfected with the ISG54-CAT reporter plasmid, a constitutively expressed Renilla luciferase reporter plasmid and empty vector (Vec) or with plasmids expressing Nipah virus W protein (W), Flag-tagged EBOV VP24 (F-24), untagged VP24 (24), or EBOV VP35 (35). Twenty-four hours posttransfection, the cells either were mock treated or were treated with 1,000 U of human IFN-ß/ml for 24 h, harvested, and then assayed for CAT and luciferase activities. The data are presented as the activation (fold) relative to empty vector, mock-treated controls. Error bars indicate means ± the standard deviation of three experiments. (B) Levels of STAT1 gene expression in 293T cells transfected with empty vector (Vec) or plasmids expressing the indicated protein are shown. Twenty-four hours posttransfection, the cells were treated with 1,000 U of IFN-ß/ml, and 18 h posttreatment, the cells were lysed and subjected to Western blot analysis with anti-STAT1 ( ${alpha}$ STAT1) and anti-ß-actin ( ${alpha}$ ß-actin) antibodies. (C) Levels of IFN- ${gamma}$ -induced reporter gene activation in Vero cells transfected with empty vector (Vec) or with plasmids expressing EBOV VP35 (35) or FLAG-tagged EBOV VP24 (24). Vero cells were transfected with the IFN- ${gamma}$ -responsive IRF-1-promoter luciferase reporter and a constitutively expressed Renilla luciferase reporter. Twenty-four hours posttransfection, the cells were either mock treated or treated with 1,000 U/ml of IFN- ${gamma}$ , and 24 h posttreatment, reporter gene activity was measured. IFN- ${gamma}$ -induced reporter values were normalized to the Renilla luciferase reporter. Results are presented as induction (fold) of the IRF-1-luciferase reporter relative to an empty vector-transfected, mock-treated control. Error bars indicate the mean ± the standard deviation of three experiments.

The ability of VP24 to inhibit IFN-induced expression of anendogenous gene, STAT1, was also assessed. (STAT1 is a key transcriptionfactor in the IFN signaling pathways, and its expression isupregulated upon IFN-ß treatment [15, 37].) After18 h of treatment with IFN-ß, a clear increase inSTAT1 protein expression was observed in cells transfected withempty vector or with VP35 expression plasmid (Fig. 1B, compareempty vector-IFN-ß- to empty vector-transfected, mock-treatedcells). In contrast, either an untagged or a FLAG-tagged VP24plasmid was able to inhibit IFN-ß-induced STAT1 expression(Fig. 1B).

Given that EBOV infection is reported to block not only IFN- ${alpha}$ /ßbut also IFN- ${gamma}$ signaling, we asked whether the antagonistic effectof VP24 extended to the IFN- ${gamma}$ pathway. For this purpose, a luciferasereporter under control of the IFN- ${gamma}$ -responsive IRF-1 promoter,which contains GAS elements was used. IFN- ${gamma}$ treatment resultedin reporter activation in empty vector-transfected cells. VP35,which is unable to inhibit IFN- ${alpha}$ /ß signaling, was alsounable to inhibit IFN- ${gamma}$ -mediated signaling. In contrast, VP24was able to inhibit reporter gene activation (Fig. 1C).

Each of the experiments described in Fig. 1 included a constitutivelyexpressed reporter plasmid to which the levels of IFN-inducedgene expression were normalized. When the expression of a constitutively-expressedRenilla luciferase gene was analyzed over the course of fourindependent transfections, luciferase values in IFN-ß-treatedcells were not statistically different in VP24-expressing versusVP35- or VP40-expressing cells (data not shown). This suggeststhat VP24 is not exerting a nonspecific, global effect upongene expression. In addition, when VP24 was transfected at aratio of 5:1 with a GFP expression plasmid and GFP-expressingcells sorted by fluorescence-activated cell sorting were analyzedfor their uptake of 7-AAD, a vital dye, we did not detect anyevidence that VP24 was cytotoxic (data not shown).

VP24 counteracts the antiviral effects of IFN-ß. The results obtained above demonstrate the ability of VP24 toinhibit the IFN-induced activation of specific IFN-responsivepromoters and the IFN-induced expression of the STAT1 gene.We next assessed the ability of VP24 to counteract the antiviraleffects of IFN-ß. Vero cells were transfected witheither empty vector, VP24 expression plasmid, or, as a positivecontrol, Nipah virus W expression plasmid. Nipah W was includedbecause it was previously demonstrated to overcome the antiviraleffects of IFN (50, 56). Twenty-four hours posttransfection,the cells were either mock treated or treated with IFN-ßand after an additional 24 h the cells were infected with NDV-GFP(50). As expected, IFN-ß treatment exerted an antiviraleffect and inhibited virus replication and thus GFP expressionin cells transfected with empty vector; whereas mock-treated,empty vector-transfected cells were able to support NDV-GFPreplication (Fig. 2, compare vector ± IFN-ßtreatment). As previously demonstrated, Nipah W expression restoredgrowth of NDV-GFP in IFN-ß-treated cells. Similarly,VP24 was able to restore growth of NDV-GFP in cells treatedwith IFN-ß (Fig. 2). Thus, expression of VP24 is sufficientto prevent the establishment, in Vero cells, of an IFN-ß-inducedantiviral state.

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FIG. 2. Ebola virus VP24 rescues growth of NDV-GFP in cells pretreated with IFN-ß. Vero cells were transfected with the empty vector (Vector) or plasmids expressing the Nipah virus W (Nipah W) or EBOV VP24 (VP24) proteins. Twenty-four hours posttransfection, the cells were mock treated (–IFNß) or treated with 1,000 U/ml of IFN-ß (+IFNß) as indicated. Twenty-four hours post-IFN-ß treatment, the cells were infected with NDV-GFP. The green fluorescence was visualized 24 h postinfection under a fluorescence microscope.

VP24 prevents IFN-induced nuclear accumulation of STAT1. The ability of VP24 to inhibit both IFN- ${alpha}$ /ß and IFN- ${gamma}$ signaling suggests that it targets a factor common to both pathways.We therefore assessed the impact of VP24 upon STAT1 (the activationof which is central to both the IFN- ${alpha}$ /ß and IFN- ${gamma}$ signalingpathways). We first asked whether VP24 expression would affect,upon IFN treatment, the nuclear accumulation of STAT1. In mock-treatedcells, immunofluorescence analysis of STAT1 revealed that theprotein was distributed in a diffuse pattern within cells. Inthe empty vector-transfected cells treated with IFN-ß,we observed prominent nuclear STAT1 in 63% of the cells (n =95). Transfection of VP35 did not alter the ability of STAT1to translocate into the nucleus. Greater than 90% of the cellsexpressing VP35 (n = 41) exhibited prominent nuclear STAT1.However, when VP24 was expressed, STAT1 failed to concentratein the nucleus following IFN-ß treatment (Fig. 3A).In cells expressing VP24, only 11% were observed to have nuclearSTAT1 (n = 48). To determine whether VP24 might globally blocknuclear import, we determined whether it affected the localizationof a GFP-IRF-3 fusion, which accumulates in the nucleus followingSendai virus infection. In contrast to the data obtained withSTAT1, VP24 did not inhibit the Sendai virus-induced nuclearlocalization of GFP-IRF-3, although as was previously reported,VP35 did block GFP-IRF-3 nuclear localization (5) (Fig. 3B).Finally, the ability of VP24 expression to inhibit IFN- ${gamma}$ -inducednuclear accumulation of STAT1 was also demonstrated (Fig. 3C).After IFN- ${gamma}$ treatment, 95% of empty vector-transfected cells(n = 78) and 92% of VP35-expressing cells (n = 36) exhibitednuclear STAT1. In contrast, only 8% of VP24-expressing cells(n = 38) exhibited nuclear STAT1. These observations suggestthat VP24 blocks IFN signaling by inhibiting STAT1 nuclear accumulation.

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FIG. 3. EBOV protein VP24 prevents IFN-mediated nuclear translocation of STAT1. (A) IFN-ß treatment (30 min) of Vero cells causes STAT1 to relocate from the cytoplasm (vector) to the nucleus (vector + IFN-ß). In cells expressing FLAG-VP24 (FLAG-VP24 + IFN-ß; relevant cells marked with an asterisk), STAT1 fails to relocate to the nucleus after IFN-ß treatment. IFN-ß treatment of FLAG-VP35-expressing cells (FLAG-VP35 + IFN-ß; relevant cells marked with an asterisk) causes STAT1 to relocate to the nucleus. Upper panels show only STAT1 images. Lower panels show the STAT1 images (green) merged with images of FLAG-tagged Ebola virus proteins (red). (B) Vero cells express GFP-IRF-3 in the cytoplasm in the absence of viral infection (vector), but translocate GFP-IRF-3 to the nucleus when infected with Sendai virus (vector + SeV). Coexpression of FLAG-VP35 prevents translocation of GFP-IRF-3 (FLAG-VP35 + SeV), but FLAG-VP24-expressing cells are still able to traffic GFP-IRF-3 to the nucleus (FLAG-VP24 + SeV). Upper panels show the GFP-IRF-3 (green) merged with Hoechst nuclear staining (blue). Lower panels show the FLAG-tagged Ebola virus proteins. (C) In Vero cells cotransfected with empty vector, STAT1 is predominately cytoplasmic in the absence of IFN- ${gamma}$ treatment (vector), but STAT1 concentrates in the nucleus after a 30-min treatment with IFN- ${gamma}$ (vector + IFN- ${gamma}$ ). In the presence of FLAG-VP24, IFN- ${gamma}$ treatment fails to relocate STAT1 to the nucleus (FLAG-VP24 + IFN- ${gamma}$ ).

VP24 prevents nuclear translocation of tyrosine-phosphorylated STAT1. Experiments were then performed to determine whether VP24 expressionaffects the IFN-induced tyrosine phosphorylation of STAT1 orthe nuclear localization of PY-STAT1. We first examined, inthe presence or absence of VP24, the location of endogenousPY-STAT1 by staining cells with a phospho-specific antibody.In control cells (Vero cells transfected with FLAG-tagged VP35),PY-STAT1 (green) appears in the nucleus after 30 min of IFN-ßtreatment (Fig. 4A). However, FLAG-VP24-expressing cells displayPY-STAT1 in the cytoplasm (Fig. 4A). To control for the specificityof this staining, we confirmed that no PY-STAT1 signal couldbe detected in the Vero cells in the absence of IFN treatment(data not shown). In a separately performed transfection, 77of 86 (89%) mock-transfected, IFN-treated cells displayed nucleartyrosine-phosphorylated STAT1 30 min post-IFN addition. Similarly,30 of 42 (71%) FLAG-VP35-transfected, IFN-treated cells displayednuclear tyrosine-phosphorylated STAT1. For these VP35 cells,there was a minority of cells which displayed high levels ofPY-STAT1 staining that had either cytoplasmic PY-STAT1 or atleast PY-STAT1 that was not in a clearly defined nucleus. Incontrast, for the IFN-treated, FLAG-VP24 transfectants, in atotal of 107 expressing cells, only 8 (7.5%) had nuclear PY-STAT1(data not shown).

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FIG. 4. VP24 prevents the nuclear translocation of phosphorylated STAT1 (Tyr 701). (A) After treatment with IFN-ß for 30 min, cells expressing FLAG-VP35 (top row, red channel) are able to translocate PY-STAT1 (P-STAT1; green channel) to the nucleus. In cells expressing FLAG-VP24 (bottom row, red channel) PY-STAT1 is located in the cytoplasm. (B) VP24 expression does not detectably inhibit the tyrosine phosphorylation of STAT1. 293T cells were transfected with expression plasmids encoding: pCAGGS empty vector (vector), luciferase, Nipah virus V (NipV), VP35, VP24, or FLAG-VP24. After treatment with IFN-ß (or mock treatment), the cells were lysed and analyzed for the presence of PY-STAT1 by Western blotting.

Since an effect of VP24 expression upon levels of PY-STAT1 mightbe difficult to detect using fluorescence microscopy, we alsoexamined STAT1 tyrosine phosphorylation by Western blottingextracts from transfected, IFN-ß-treated 293T cells,30 min following IFN-ß-treatment. Both FLAG-VP35-and FLAG-VP24-transfected cells contained amounts of PY-STAT1similar to that seen in cells expressing no recombinant proteinor an irrelevant protein, luciferase (Fig. 4B). In a controlsample, expression of the Nipah virus V protein, which has beenshown to prevent STAT1 phosphorylation (52, 56), reduced theamount of PY-STAT1 (Fig. 4B). We conclude that VP24 inhibitstranscriptional responses to IFN, at least in part, by preventingthe normal trafficking of PY-STAT1 to the nucleus.

Expression of supraphysiological intracellular concentrationsof VP24 could conceivably lead to effects of VP24 not seen inEBOV-infected cells. To address this concern, Western blotswere performed on cell lysates prepared from EBOV-infected andVP24-transfected cells. The lysates for this experiment werederived from Vero cells infected such that 50% of cells stainedpositive for viral antigen or Vero cells transfected with FLAG-VP24such that approximately 40% of cells were stained by anti-FLAGantibody. A significantly stronger VP24 signal was detectedfrom the infected cell lysate versus the transfected cell lysate(data not shown). Thus, the transfection experiments describedabove appear to involve biologically relevant levels of VP24.

EBOV infection inhibits both IFN-ß-induced gene expression and nuclear accumulation of PY-STAT1. If VP24 contributes to the inhibition of IFN signaling by EBOV,EBOV infection should inhibit the nuclear transport of PY-STAT1.To address this hypothesis, we infected Vero cells with EBOV(MOI = 1) and, 24 h postinfection, treated them overnight withIFN-ß. By Western blotting, MxA, a protein whose expressionis induced by interferon (1), was found to be up-regulated followingIFN-ß treatment in mock-infected cells, but this up-regulationwas absent in EBOV-infected cells (Fig. 5A). Infection of thecells was confirmed by examining expression of the VP24 protein(Fig. 5A). These data are consistent with previous reports thatEBOV infection blocks IFN signaling (27). In a separate experiment,Vero cells were grown on glass coverslips, infected with EBOV(MOI = 0.5), and, 24 h postinfection, treated with IFN-ßfor 30 min. After fixation, the cells were processed for immunofluorescenceanalysis of PY-STAT1 and of viral antigen (the VP35 protein).Greater than 90% of cells lacking significant viral antigenstaining (n = 74) demonstrated nuclear STAT1 (Fig. 5B, upperpanel). Consistent with the data obtained when VP24 was expressedby transfection, we observed that only 21% of EBOV-infectedcells (n = 80) accumulated PY-STAT1 in their nucleus (Fig. 5B,lower panel). It should be noted that, in these experiments,cells were infected at an MOI of 0.5 and examined 48 h postinfection.Under these conditions, it is likely that more than one roundof infection was initiated in these cultures, and thus someof the infected cells were probably expressing only low levelsof VP24.

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FIG. 5. EBOV infection inhibits IFN-ß-induced expression of MxA and prevents nuclear translocation of PY-STAT1. (A) Mock-infected Vero cells express MxA in response to overnight treatment with IFN-ß (lane 2). However, EBOV-infected cells (MOI = 1) do not produce MxA in response to IFN-ß (lane 4). Lanes 1 and 2 were mock infected. Lanes 3 and 4 were infected with EBOV. Lanes 2 and 4 were treated with IFN-ß, while lanes 1 and 3 were mock treated. (Top panel) Western blot to detect MxA and GAPDH. (Bottom panel) Western blot to detect VP24. (B) Mock-infected Vero cells translocate PY-STAT1 to the nucleus after 30 min of IFN-ß treatment (top panel), but EBOV-infected cells retain PY-STAT1 in the cytoplasm (bottom panel). Red represents viral antigen (VP35), and green represents PY-STAT1.

VP24 interacts with the STAT1 nuclear localization signal receptor, karyopherin ${alpha}$ 1, and inhibits VP24-PY-STAT1 interaction. PY-STAT1 is reported to accumulate in the nucleus via interactionwith a specific nuclear localization signal receptor, karyopherin ${alpha}$ 1 (45, 48, 55). Given the ability of VP24 to prevent the nuclearaccumulation of STAT1, we asked whether VP24 might interactwith this or other nuclear localization signal receptors. FLAG-taggedkaryopherin ${alpha}$ 1, ${alpha}$ 2, ${alpha}$ 3, or ${alpha}$ 4 expression plasmid was cotransfectedwith empty plasmid, untagged VP24 expression plasmid, or VP35expression plasmid. One day posttransfection, immunoprecipitationswere performed with an anti-FLAG monoclonal antibody, and theprecipitated material was analyzed by Western blotting withantibodies recognizing FLAG, VP24, or VP35. VP24 coprecipitatedexclusively with karyopherin ${alpha}$ 1 (Fig. 6A). In contrast, VP35did not coprecipitate with any of the karyopherin ${alpha}$ s (data notshown).

To determine if the interaction of VP24 with karyopherin ${alpha}$ 1 mightaccount for the loss of STAT1 nuclear accumulation, we askedif VP24 is able to disrupt the STAT1-karyopherin ${alpha}$ 1 interaction.FLAG-tagged karyopherin ${alpha}$ 1 was coexpressed with or without STAT1-GFPin the presence and absence of VP24. In the absence of IFN-ß(Fig. 6B, lanes 1 to 3), no STAT1-GFP was coprecipitated withthe karyopherin ${alpha}$ 1, despite the presence of STAT1-GFP in thewhole-cell lysates (Fig. 6B, lanes 1 and 3). However, followingaddition of IFN-ß to the cells (Fig. 6B, lanes 4 to6), STAT1-GFP coprecipitated with karyopherin ${alpha}$ 1 (Fig. 6B, lane4). VP24 was once again coprecipitated with karyopherin ${alpha}$ 1, regardlessof whether or not IFN-ß was added (Fig. 6B, lanes2, 3, 5, and 6). Most significantly, STAT1-GFP did not associatewith karyopherin ${alpha}$ 1 when VP24 was present (Fig. 6B, lane 6).To determine whether there is a dose-dependent effect of V24on karyopherin ${alpha}$ 1-STAT1 interaction, we coexpressed STAT1-GFPwith karyopherin ${alpha}$ 1 (Fig. 6C, lanes 1 to 5) or without karyopherin ${alpha}$ 1 (Fig. 6C, lane 6). VP24 either was not expressed (Fig. 6C,lane 1) or was expressed in increasing amounts (lanes 2 to 5).The cells were treated with IFN-ß, and immunoprecipitationof the FLAG-karyopherin ${alpha}$ 1 was performed. In this experiment,detection of STAT1-GFP was performed with anti-PY-STAT1 antibody,which, in our hands, is more sensitive than the Western blotfor total STAT1. Western blotting was also performed to detectFLAG-karyopherin ${alpha}$ 1 and VP24. As was seen previously, the activatedSTAT1-GFP coprecipitated with karyopherin ${alpha}$ 1 when VP24 was absent(Fig. 6C, lane 1). In contrast, no STAT1-GFP was precipitatedwith anti-FLAG antibody when the Flag-karyopherin ${alpha}$ 1 was omitted(Fig. 6C, lane 6). When a low level of VP24 was present in theprecipitation, less PY-STAT1-GFP was coprecipitated (Fig. 6C,lane 2). When higher levels of VP24 were present, the levelof STAT-GFP coprecipitated was further decreased (Fig. 6C, lanes2 to 5). These data suggest that the interaction of VP24 withkaryopherin ${alpha}$ 1 inhibits karyopherin ${alpha}$ 1-PY-STAT1 association, thusproviding an explanation as to how VP24 may inhibit STAT1 nuclearaccumulation.

DISCUSSION

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Discussion

The data described above provide a molecular explanation forthe impaired cellular responses to IFN- ${alpha}$ /ß and to IFN- ${gamma}$ in EBOV-infected cells and shed further light on the abilityof this highly lethal pathogen to modulate the host IFN system.Previously, it was demonstrated that EBOV-infected human umbilicalvein endothelial cells did not respond to either IFN- ${alpha}$ treatmentor IFN- ${gamma}$ treatment (27). Specifically, the up-regulation of severalIFN- ${alpha}$ /ß- or IFN- ${gamma}$ -induced genes was absent or reducedin the infected cells (27). However, IL-1ß-inducedexpression of IL-6 and ICAM-1 was intact, demonstrating thatinfection did not globally block transcriptional responses toall cytokines (27). Electrophoretic mobility shift assays onnuclear extracts further demonstrated that in EBOV-infectedcells, IFN- ${alpha}$ - and IFN- ${gamma}$ -induced nuclear transcription factor complexeswere absent or were present in greatly reduced amounts (27).The present study more clearly defines the EBOV-imposed blockto the IFN- ${alpha}$ /ß and IFN- ${gamma}$ signaling pathways and identifiesa single viral protein, VP24, capable of exerting this function.EBOV infection and VP24 expression appear to have equivalenteffects upon these signaling pathways. In both cases, the tyrosinephosphorylation of STAT1 in response to IFN remains intact.Rather, the critical step blocked by either EBOV infection orby VP24 expression, is the nuclear accumulation of STAT1 (Fig.4 and 5). Of note, VP24 does not globally inhibit nuclear translocationof proteins, as it did not prevent the Sendai virus-inducednuclear accumulation of GFP-IRF-3 (Fig. 3). The latter observationis consistent with the view that EBOVs utilize a second protein,VP35, to block activation of IRF-3 (5-8, 28, 51).

The nuclear localization of STAT1 (reviewed in references 47and 49) is triggered by its tyrosine phosphorylation-induced,SH2 domain-dependent dimerization (23, 54, 57, 58). In its inactivestate, STAT1 shuttles between the cytoplasm and nucleus viaan energy-independent mechanism involving direct interactionswith nucleoporins (44). Tyrosine phosphorylation results inSTAT1 heterodimerization with STAT2 (following IFN- ${alpha}$ /ßtreatment) or STAT1 homodimerization (following IFN- ${gamma}$ treatment)(reviewed in reference 38). Dimerization of STAT1 results inconformational changes revealing an atypical NLS. This NLS directlyinteracts with the carboxy-terminal armadillo repeats of karyopherin ${alpha}$ 1 (importin ${alpha}$ 5). Given that activated STAT1 did not detectablyinteract with other karyopherin ${alpha}$ proteins, including karyopherin ${alpha}$ 2 (importin ${alpha}$ 1, Rch1) and karyopherin ${alpha}$ 4 (importin ${alpha}$ 3, Qip1), orimportin ${alpha}$ 7, it may be only karyopherin ${alpha}$ 1 which mediates nuclearaccumulation of PY-STAT1 (45, 48, 55). Following its nuclearaccumulation, DNA containing STAT1 binding sequences can competewith karyopherin ${alpha}$ 1 for binding to STAT1 homodimers, allowingSTAT1 to interact with its target promoters (17, 45). Ultimately,nuclear STAT1 is dephosphorylated, dissociates from DNA, andis exported to the cytoplasm in a CRM1-dependent manner (29,30, 44, 46, 47). Our data do not provide any evidence that VP24prevents the tyrosine phosphorylation of STAT1, but they dodemonstrate an inhibition of STAT1 nuclear import.

It was interesting to note, given its ability to inhibit nuclearaccumulation of STAT1, that VP24 is reported to exhibit a largelyperinuclear localization in EBOV-infected cells (25). Thus,VP24 would seem appropriately positioned to influence nuclear/cytoplasmictransport. We therefore tested VP24 for the ability to interactwith karyopherin ${alpha}$ proteins. VP24 selectively interacted, incoimmunoprecipitation studies, with karyopherin ${alpha}$ 1, the previouslyidentified NLS receptor for STAT1 (45, 48, 55). That this interactionmay mediate the observed defect in STAT1 nuclear import is supportedby the ability of VP24 to prevent the association of an activatedSTAT1-GFP protein with karyopherin ${alpha}$ 1 (Fig. 6). This selectiveinteraction of VP24 with karyopherin ${alpha}$ 1 likely also explainswhy VP24 does not inhibit the nuclear import of IRF-3, as thenuclear import of this protein has been attributed to karyopherin ${alpha}$ 3 and ${alpha}$ 4 (36) (Fig. 3). However, further studies will be requiredto address the possibility that VP24 may also influence thenuclear import of other molecules that use karyopherin ${alpha}$ 1.

EBOV is an enveloped, nonsegmented negative-strand RNA viruswith a genome of approximately 19 kb, and VP24 is one of eightmajor EBOV-encoded proteins (53). Although several functionshave previously been attributed to the EBOV VP24 protein, itsprecise role in viral replication remains ambiguous and somewhatcontroversial. Early studies suggested that VP24 is found inEBOV virions and, as a consequence, VP24 was postulated to bea "minor matrix protein" or to function in viral uncoating (16,53). Although the primary EBOV matrix protein is VP40, and VP40appears to be the principal force driving the budding of EBOVparticles, recent studies do support a possible role for VP24in viral budding. In particular, VP24 oligomerizes, is hydrophobic,and associates with cellular membranes, all properties characteristicof viral matrix proteins (25). In addition, VP24 itself appearsto bud at some level from cells (25). However, coexpressionof VP24 with VP40 did not appear to enhance budding by VP40(40). In addition, VP24 may play an important role in assemblyof viral nucleocapsids as EBOV nucleocapsids could be reconstitutedby coexpression of the EBOV nucleoprotein (NP), VP35, and VP24(31). VP24 could be coimmunoprecipitated with NP and VP35 (31);however, VP24 did not cosediment with NP and VP35 in densitygradients, suggesting that, while it promotes nucleocapsid formation,it may not be an essential component of the nucleocapsid structure(31). In a different study, VP24 was not required for eitherthe formation or the infectivity of Ebola virus-like particlescarrying an EBOV minigenome (63). More recently, the use ofsmall interfering RNAs targeting Marburg virus VP24 supportsa role for this protein in filovirus assembly and release frominfected Vero cells (3). Given this array of potential functions,it will be of interest to determine which of these is influencedby the ability of VP24 to block IFN signaling pathways or tointeract with karyopherin ${alpha}$ 1.

Understanding the determinants of EBOV virulence in differentspecies may provide insights into EBOV pathogenesis in humansand may suggest novel therapeutic approaches. The IFN systemhas been clearly implicated in the susceptibility of mice toEBOV disease (9, 12, 42), and the sequence of VP24, along withthat of several other genes, changed following the adaptation,by serial passage, of Zaire EBOV to mice (10). (The full sequenceof the mouse-adapted EBOV is available under GenBank accessionno. AF499101.) It is therefore intriguing that adaptation ofEBOV to another host, guinea pigs, is also associated with changesin VP24. Specifically, adaptation of a Zaire EBOV from a nonlethalform to a form lethal to guinea pigs was associated with 5 aminoacid changes, one each in the nucleoprotein and L (polymerase),and 3 amino acid changes in VP24 (61). Sequence analysis ofthe VP24 gene from an independently adapted EBOV also identifiedan amino acid change in VP24, and it was suggested, based onthese observations, that changes in VP24 are likely to playan important role in guinea pig adaptation (61). Although STAT1and karyopherin ${alpha}$ 1 are highly conserved between human and mouse,with each protein displaying greater than 90% amino acid identitybetween the two species, it will be of interest to determinewhether these changes in VP24 result in an enhanced abilityto counteract interferon responses in these new hosts and whetherthe adaptation of EBOV to the new species correlates with anincreased affinity of VP24 for karyopherin ${alpha}$ molecules of thenew host.

At present, no vaccines against EBOV are licensed for use inhumans, although experimental vaccines that are effective innonhuman primates have been described (34, 59, 60). In addition,no antivirals are available to treat these severe infections,although an inhibitor of tissue factor was found to offer someprotection to experimentally infected nonhuman primates (19).The ability of VP24 to block IFN signaling pathways has obviousimplications for the efficacy of IFN as an anti-EBOV therapy.Although 200 IU/ml of IFN- ${alpha}$ 2b was found to inhibit EBOV replication100-fold in Vero cells (33), daily intramuscular treatment ofEBOV-infected monkeys with a relatively high dose of IFN- ${alpha}$ 2bbeginning 18 h postinoculation merely delayed viremia and deathby about 1 day (33). These data suggest that IFNs have limitedefficacy against EBOV and fit with the view that VP24 expressionrenders EBOV relatively insensitive to IFN. Despite these observations,the mouse model of infection suggests that IFNs might be employedto effectively control EBOV infection. For example, mouse-adaptedZaire EBOV is lethal to mice following intraperitoneal infectionbut not following subcutaneous infection (42). Subcutaneousadministration of the mouse-adapted virus conferred protectionfrom challenge with an otherwise lethal intraperitoneal dose,even at 48 h postinoculation (42). This early time point, priorto the development of EBOV-specific adaptive immune responses,correlated with peak induction of IFN- ${alpha}$ levels, suggesting thatIFN- ${alpha}$ /ß can have a therapeutic effect on EBOV infection(42). Additionally, the adenosine analog 3-deazaneplanocin Awas found to protect mice from illness and death following infectionwith mouse-adapted EBOV (32). Protection by this drug appearsto involve the induction of large quantities of IFN- ${alpha}$ (12). Ourdata suggest that the anti-EBOV efficacy of IFNs might be augmentedby inhibitors of VP24. Additional studies to further definethe mechanism by which VP24 functions should facilitate thedevelopment of such therapies.

ACKNOWLEDGMENTS

This work was supported by grants to C.F.B. from the NationalInstitutes of Health and grants to V.E.V. from INSERM, DeutscheForschungsgemeinschaft (SFB 593), and from French Ministèrede la Recherche (04G537). C.F.B. is an Ellison Medical FoundationNew Scholar in Global Infectious Diseases.

We thank Luis Martínez-Sobrido and Adolfo García-Sastre(Mount Sinai School of Medicine) for providing the GFP-IRF-3and IRF-9 expression plasmids; Georg Kochs and Otto Haller (Universityof Freiberg) for providing anti-MxA antibody and the IRF-1-luciferasereporter plasmid; and David E. Levy (New York University) forproviding the ISG54-CAT reporter plasmid.

FOOTNOTES

* Corresponding author. Mailing address: Department of Microbiology, Box 1124, Mount Sinai School of Medicine, 1 Gustave L. Levy Place, New York, NY 10029. Phone: (212) 241-4847. Fax: (212) 534-1684. E-mail: chris.basler{at}mssm.edu.

S.P.R. and L.W.L. contributed equally to this study.

REFERENCES

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