Constitutive Activation of the Transcription Factor NF-{kappa}B Results in Impaired Borna Disease Virus Replication

The inducible transcription factor NF- ${kappa}$ B is commonly activatedupon RNA virus infection and is a key player in the inductionand regulation of the innate immune response. Borna diseasevirus (BDV) is a neurotropic negative-strand RNA virus, whichreplicates in the nucleus of the infected cell and causes apersistent infection that can lead to severe neurological disorders.To investigate the activation and function of NF- ${kappa}$ B in BDV-infectedcells, we stably transfected the highly susceptible neuronalguinea pig cell line CRL with a constitutively active (IKK EE)or dominant-negative (IKK KD) regulator of the IKK/NF- ${kappa}$ B signalingpathway. While BDV titers were not affected in cells with impairedNF- ${kappa}$ B signaling, the expression of an activated mutant of I ${kappa}$ Bkinase (IKK) resulted in a strong reduction in the intracellularviral titer in CRL cells. Electrophoretic mobility shift assaysand luciferase reporter gene assays revealed that neither NF- ${kappa}$ Bnor interferon regulatory factors (IRFs) were activated uponacute BDV infection of wild-type or vector-transfected CRL cells.However, when IKK EE-transfected cells were used as target cellsfor BDV infection, DNA binding to an IRF3/7-responsive DNA elementwas detectable. Since IRF3/7 is a key player in the antiviralinterferon response, our data indicate that enhanced NF- ${kappa}$ B activityin the presence of BDV leads to the induction of antiviral pathwaysresulting in reduced virus titers. Consistent with this observation,the anti-BDV activity of NF- ${kappa}$ B preferentially spread to areasof the brains of infected rats where activated NF- ${kappa}$ B was notdetectable.

INTRODUCTION

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Introduction

Borna disease virus (BDV), a noncytolytic single-stranded RNAvirus, is the only known member of the Bornaviridae of the orderMononegavirales (51). BDV is highly neurotropic and cell associatedand leads to a persistent infection of the central nervous system(54). BDV induces Borna disease (BD), a T-cell-mediated encephalomyelitis,in a wide variety of animals, including cattle, cats, dogs,and birds (reviewed in reference 31). Furthermore, BD virus,nucleic acids, antigens, and antibodies have been detected inthe blood of patients with psychiatric diseases (2, 7, 29, 39,35), although no direct correlation between BDV as a causativeagent and a particular mental disorder in humans has yet beendemonstrated. The infiltrating immune cells have been characterizedas CD4⁺ or CD8⁺ T cells and macrophages (6, 13, 43). CD8⁺ Tcells represent the effector cell population (22, 36, 41, 46).No evidence has been presented that antibodies might contributeto neuropathology, although neutralizing antibodies apparentlycontrol viral tropism and can prevent the spread of virus fromperipheral infection sites to the central nervous system (19,52). Analyses of BDV-infected brain tissue revealed the presenceof mRNAs encoding interleukin-1 ${alpha}$ (IL-1 ${alpha}$ ), IL-1ß, IL-2,IL-6, transforming growth factor beta, tumor necrosis factoralpha, and gamma interferon (IFN- ${gamma}$ ) (42, 48). IFN- ${alpha}$ /ßwas also found in BDV-infected cell cultures and was shown toinhibit BDV replication (20, 50, 56). In addition, a varietyof chemokine-encoding mRNAs are upregulated in BDV-infectedbrain tissue (9, 25, 45).

The 8.9-kb negative-strand BDV genome is replicated in the nucleusof the infected cell and codes for at least six different knownviral proteins (reviewed in reference 26). The nucleoprotein,which is involved in nuclear transport processes, is presentboth in the cytoplasm and in the nuclei of infected cells andforms complexes with the phosphoprotein and p10 (5, 59). Atleast one protein, p24, is phosphorylated at serine residues,suggesting that the function of this protein is controlled bycellular kinases (47, 55). Our knowledge of the interactionsof BDV with host cell functions has increased during the lastfew years. It has been shown that BDV infection interferes withthe activation of the Raf/MEK/ERK signaling cascade and thatthe blockade of this pathway results in reduced viral spread(21, 37). Furthermore, it has been demonstrated that the interactionof the viral nucleoprotein with the Cdc2/cyclin B1 complex resultsin prolongation of the G₂ phase (38).

The transcription factor NF- ${kappa}$ B is involved in the regulationof many cellular processes, including apoptosis and host defense.A variety of stimuli initiate different signaling pathways leadingto NF- ${kappa}$ B activation. Most of these pathways converge on the I ${kappa}$ Bkinase (IKK) signalosome complex, which plays a major role inNF- ${kappa}$ B activation (24). In addition, NF- ${kappa}$ B is activated by multiplefamilies of viruses, including human immunodeficiency virustype 1, human T-cell leukemia virus type 1, the hepatitis Band C viruses, Epstein-Barr virus, vesicular stomatitis virus(VSV), and influenza viruses (reviewed in references 23 and32). While for some of these viruses, e.g., retroviruses oroncogenic viruses, the activation of this transcription factormay support viral replication, it is a general belief that NF- ${kappa}$ Bacts antivirally upon infection with RNA viruses such as VSVor influenza virus (11, 57). RNA virus infections commonly resultin the activation of an innate antiviral response mediated byIFN- ${alpha}$ /ß. This antiviral program is initiated by viralinduction of the IFN-ß gene through constitutivelyexpressed transcription factors, namely AP-1, interferon regulatoryfactor 3 (IRF-3), and NF- ${kappa}$ B (58). A common viral inducer of NF- ${kappa}$ B-dependentresponses appears to be double-stranded RNA (dsRNA). Most RNAviruses, including BDV, produce dsRNA-like intermediates, representinga shared molecular pattern that may be sensed by the cell asan alert signal (33).

The interferon regulatory factors (IRFs) belong to a familyof transcription factors that commonly possess a novel helix-turn-helixDNA binding motif. Their functional role is regulation of thehost defenses, such as innate and adaptive immune responsesand oncogenesis, which are mediated through interactions withthemselves or other members of this family of transcriptionfactors (54). IRF-3 and IRF-7 are especially important for theinduction of an IFN- ${alpha}$ /ß response. While IRF-7 is anIFN-induced gene, the IRF-3 mRNA is expressed constitutivelyin all tissues (3). Both IRF-3 and IRF-7 reside in the cytoplasmin a latent form and translocate to the nucleus upon activation(30, 44, 58). Recent reports indicated that Toll-like receptors(TLRs) activate IRF-3 and NF- ${kappa}$ B via a newly defined pathway involvinginhibitor of ${kappa}$ B kinase ${varepsilon}$ (IKK ${varepsilon}$ ) and TANK (TRAF family member-associatedNF- ${kappa}$ B activator)-binding kinase 1 (TBK-1) for IFN- ${alpha}$ /ßexpression (reviewed in reference 4).

For the present study, the involvement of NF- ${kappa}$ B during BDV infectionwas investigated. BDV infection did not lead to NF- ${kappa}$ B activationin CRL cell cultures. An enhanced activation of NF- ${kappa}$ B by theexpression of an active mutant of IKK resulted in dramaticallyreduced BDV virus titers concomitant with a specific DNA bindingactivity of IRFs to an IRF-3/7-responsive element. This indicatesthat active NF- ${kappa}$ B has an antiviral effect on BDV but that BDVavoids activating NF- ${kappa}$ B in the host cell. This was also observedin vivo during acute BDV infections of rats, as BDV infectivitywas not found in cells in which NF- ${kappa}$ B was activated.

MATERIALS AND METHODS

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Materials and Methods

Cell lines, virus, and animals. The guinea pig cell line CRL 1405 was subcloned, and cells thatwere highly susceptible to BDV infection were used as a standardlaboratory cell line for BDV infection (19). Furthermore, Verocells were used throughout this study. Cells were cultured inIscove's modified Eagle's medium (IMDM) supplemented with 5%fetal calf serum (FCS), 2 mM L-glutamine, and 100 U/ml gentamicin.

The fourth rat passage of the Giessen BDV strain He/80 was usedfor infections (40). In general, adherent cells were infectedwith a multiplicity of infection (MOI) of 0.01 to 1 in either96-well or 6-well plates for 1 h in a volume of 25 µl(for 96-well plates) or 200 µl (for 6-well plates) ofIMDM-2% FCS. For mock infections, 10% normal rat brain homogenatein IMDM-2% FCS was used. Thereafter, culture medium was addedand the cells were cultivated for 5 to 7 days.

Female Lewis rats were obtained from the animal breeding facilitiesat the Friedrich Loeffler Institut, Bundesforschungsinstitutfür Tiergesundheit, Tübingen, Germany. At the ageof 6 weeks, the rats were infected intracerebrally in the leftbrain hemisphere with 0.05 ml of BDV, corresponding to 5 x 10³focus-forming units.

Retroviral infection of CRL 1405 cells. The retroviral expression vectors and stable producer cell linesused for this study were described previously (12). Two daysbefore infection, CRL cells were seeded in six-well plates ata density of 5 x 10⁴ cells/well. For infections, cell culturesupernatants containing the retroviral vectors were added tothe CRL cells and the culture plates were centrifuged at 100x g for 3 h. Thereafter, the supernatants were replaced withculture medium. The transfection efficiency was controlled for2 days after infection, and if the transfection efficiency wasbelow 20%, the infection procedure was repeated to increasethe efficiency of infection/transfection, which ranged between20 and 50%. The cells were cultured in the presence of 1 mg/mlzeocin (Invitrogen) for 2 weeks or until all cells were positivefor green fluorescent protein (GFP), which was monitored byfluorometric analysis using a FACSCalibur flow cytometer (BectonDickinson). Prior to each experiment, the cells were again screenedfor GFP fluorescence.

Electrophoretic mobility shift assay (EMSA). For preparations of nuclear extracts, 2 x 10⁵ CRL cells wereseeded in 60-mm cell culture dishes and either infected withBDV (MOI = 1) or left uninfected on the next day. After 6 days,uninfected cells were stimulated with tetradecanoyl phorbolacetate (TPA; 0.3 µg/ml) for 40 min. Cells were washedtwice with cold phosphate-buffered saline (PBS) and then harvestedin 400 µl of buffer A (10 mM KCl, 10 mM HEPES [pH 7.9],0.1 mM EDTA, 0.1 mM EGTA, 1 mM dithiothreitol [DTT], and 1 mMphenylmethylsulfonyl fluoride). After 15 min of shaking at 4°C,25 µl 10% Nonidet P-40 was added for 2 min, and the nucleiwere pellet and resuspended in 50 µl of buffer B (20 mMHEPES [pH 7.9], 0.4 M NaCl, 1 mM EDTA, 1 mM EGTA, and 1 mM DTT).After 20 min of shaking and subsequent centrifugation, the proteinconcentrations of the nuclear extracts were determined (Bio-Rad,Germany). Eight micrograms of nuclear extract was incubatedwith 4 µg poly(dI-dC)² in binding buffer (0.1 M KCl, 10mM Tris-HCl [pH 7.5], 5 mM MgCl₂, 1 mM DTT, and 10% glycerol).After 20 min, 2 x 10⁴ to 5 x 10⁴ cpm of a ³²P-labeled double-strandedoligonucleotide (5'-GATCCAGAGGGGACTTTCCGAGTAC-3') was addedto the mixture and further incubated for 10 min at room temperature.Thereafter, the samples were separated in nondenaturing 5% polyacrylamidegels. After drying, the gels were subjected to autoradiography.

Luciferase reporter gene assay. Cells (2.5 x 10⁴) in 24-well plates were transfected with 0.05µg 3x ${kappa}$ B reporter plasmid and 0.1 µl Lipofectamine2000 (Invitrogen). After 5 h, the cells were stimulated with0.3 µg/ml TPA. Twenty-four hours after transfection, thecells were harvested in 100 µl of lysis buffer (50 mMsodium morpholineethanesulfonic acid [Na-MES], 50 mM Tris-HCl[pH 7.5], 0.2% Triton X-100, and 1 mM DTT). The lysates werecentrifuged for 5 min at 15,000 x g. For determination of theluciferase activity, 20 µl of cleared lysate was addedto 50 µl of assay buffer (125 mM Na-MES, 125 mM Tris-HCl[pH 7.5], 25 mM magnesium acetate, and 2.5 mg/ml ATP) and quantifiedin a luminometer (Lumat LB 9501) using 50 µl of substratesolution (0.5 mM Luciferin, 1 mM NaOH). For normalization, proteinconcentrations were determined by the Bradford method (Bio-Rad).

Infectivity assay. Virus infectivity was determined by the use of CRL 1405 cells.The cells were cultured for 7 days in the presence of differentdilutions of BDV-infected cell lysates in flat-bottomed 96-wellmicrotiter plates. Thereafter, cells were fixed with 4% paraformaldehyde-PBSand permeabilized with 1% Triton X-100-PBS. The presence ofviral antigens was demonstrated by an immunohistochemical reactionusing mouse anti-BDV monoclonal antibodies. The nonspecificbinding of immunological reagents was blocked by incubationof the plates with 10% fetal calf serum-PBS. The reaction ofmonoclonal antibodies with cells was detected by use of a secondaryanti-species biotin-labeled antibody (Dianova) and a streptavidin-peroxidaseconjugate (Dianova). The reaction was visualized with ortho-phenylenediamineand H₂O₂ (Sigma).

Treatment with interferon. CRL cells were infected with BDV (MOI = 0.1) and at 3 days postinfection(p.i.) were treated with either 100, 10, or 1 U of universalIFN- ${alpha}$ /ß (PBL Biomedical Laboratories) for an additional3 days in 3 ml of culture medium. Thereafter, the viral infectivitywas determined by the standard assay described above.

Immunohistochemistry. Brain samples were obtained at different time points after infectionand were fixed in 4% paraformaldehyde. All tissue sections werestained with hematoxylin-eosin. Immunohistochemistry was carriedout for the presence of BDV-specific antigens, using an anti-BDVnucleoprotein-specific mouse monoclonal antibody (38/17C1) (55)as described previously (18), and for the detection of activatedNF- ${kappa}$ B, using a pNF- ${kappa}$ B (p65) phospho-specific rabbit antibody (NEB)at a 1:50 dilution. The staining reaction was enhanced by useof a biotinylated secondary antibody (1:200). For detection,an ABC kit (Vector) was used.

RESULTS

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Results

Generation of stably transfected cell lines with mutated IKK/NF- ${kappa}$ B signaling pathway. To investigate the role of the IKK/NF- ${kappa}$ B signaling module inBDV infection, we used retroviral gene transfer to generateVero cells and highly BDV-susceptible CRL cells stably overexpressingIKK either as dominant-negative (IKK KD) or constitutively active(IKK EE) mutants. Furthermore, a nondegradable mutant of theinhibitor of NF- ${kappa}$ B ${alpha}$ (mI ${kappa}$ B ${alpha}$ ) and a control cell line expressing theempty retroviral vector (VEC) were generated. Since the vectorused expresses GFP from the same mRNA as the transgene, successfultransduction could be controlled by fluorocytometric analysisprior to each experiment of this study (Fig. 1A). TPA stimulationresulted in the transcriptional activation of NF- ${kappa}$ B in CRL andVero cells stably transfected with the VEC construct or IKKEE. Reduced transcriptional activation of NF- ${kappa}$ B was found inIKK KD cells, while mI ${kappa}$ B ${alpha}$ cells showed an efficient block of NF- ${kappa}$ Bactivation, as demonstrated with the luciferase reporter geneassay (Fig. 1B). Thus, IKK EE expression resulted in a slightlyenhanced NF- ${kappa}$ B activity, while in cells expressing the dominant-negativemutant, NF- ${kappa}$ B was functionally knocked down. The relative lightunits/µg of protein presented in Fig. 1B were 3,748.96± 122.56 for CRL-VEC cells and 10,193.07 ± 434.62for CRL-IKK EE cells without TPA stimulation, demonstratingthat NF- ${kappa}$ B activity was already increased in IKK EE cells comparedto controls. Furthermore, NF- ${kappa}$ B activity induced by TPA stimulationcould be inhibited by using the specific inhibitor Bay 117082(Fig. 1C).

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FIG. 1. Characterization of CRL and Vero IKK/I ${kappa}$ B mutant cell lines. (A) Fluorescence-activated cell sorting analyses of stably transfected CRL and Vero cells harboring either the empty control vector (VEC), a constitutive form of IKK (IKK EE), a dominant-negative form of IKK (IKK KD) or an inactive mutant of I ${kappa}$ B (I ${kappa}$ Bm). (B) NF- ${kappa}$ B-luciferase reporter gene assay. Stably transfected Vero or CRL cells were transfected with a luciferase reporter gene plasmid driven by a 3x ${kappa}$ B binding site containing an artificial promoter. Five hours after transfection, cells were treated with 0.3 µg/ml TPA and were harvested 16 h later for luciferase assays to indicate NF- ${kappa}$ B activation. The bars represent averages and standard deviations of three independent transfections. Results are shown as fold increases over the control. The relative light units/µg of protein were 3,748.96 ± 122.56 for CRL-VEC cells and 10,193.07 ± 434.62 for CRL-IKK EE cells. (C) Inhibition of NF- ${kappa}$ B with Bay 117082 (1 µM).

Reduced BDV titers in CRL-IKK EE cells. IKK/I ${kappa}$ B mutant CRL cell lines were infected with BDV at an MOIof 0.01 for 6 days to scrutinize whether manipulation of theIKK/NF- ${kappa}$ B signaling pathway has an influence on BDV replication.Cells were lysed and virus titers were determined by use ofa standard focus-forming assay. In CRL-VEC, CRL-IKK KD, andCRL-mI ${kappa}$ B ${alpha}$ cells, similar virus titers of roughly 4.0 log₁₀/10⁶cells were found. In contrast, in CRL-IKK EE cells, the virustiters were strongly reduced (2.5 log₁₀/10⁶ cells) comparedto the other mutant cell lines (Fig. 2A). The same results wereobtained when CRL mutants were infected at an MOI of 0.1 (forCRL-VEC, 4.1 log₁₀; for CRL-IKK KD, 4.1 log₁₀; for CRL-IKK EE,2.6 log₁₀; for CRL-mI ${kappa}$ B ${alpha}$ , 4.4 log₁₀). Since Vero cells have achromosomal deletion of the alpha and beta-1 interferon genes,they are not able to produce IFN- ${alpha}$ /ß (14). IKK/I ${kappa}$ B mutantVero cell lines were infected with BDV at an MOI of 0.01 for6 days to further investigate the role of the IKK/NF- ${kappa}$ B signalingpathway and IFN- ${alpha}$ /ß in BDV replication in more detail.Although in contrast to the case for CRL cells, BDV virus titerswere generally lower in Vero-VEC, Vero-IKK KD, and Vero-mI ${kappa}$ B ${alpha}$ cells (roughly 2.8 log₁₀/10⁶ cells), no reduction in the BDVinfectivity of Vero-IKK EE cells was found (Fig. 2B). Again,after infection at an MOI of 0.1, similar results were found(data not shown). These results indicate that BDV infectivityseems to be controlled by active NF- ${kappa}$ B, most likely through theinduction of IFN- ${alpha}$ /ß. Therefore, supernatants of BDV-infectedCRL-IKK/I ${kappa}$ B mutant cell lines were collected and tested for IFN- ${alpha}$ /ßactivity in a VSV-based bioassay. Interferon was detectablein small amounts only in the supernatants of BDV-infected CRL-IKKEE cells, but not in those of other infected cell lines or uninfectedcells (data not shown). To demonstrate that IFN- ${alpha}$ /ßis able to control BDV in cell culture, we infected CRL cellswith BDV, and 3 days after infection, treated them with IFN- ${alpha}$ /ß.Surprisingly, at this time already a treatment with 1 U of IFN- ${alpha}$ /ßled to a 50% reduction in the virus titer. Incubation with 100U of IFN- ${alpha}$ /ß resulted in a reduction of 90%, indicatingthe high sensitivity of BDV to IFN- ${alpha}$ /ß (Fig. 2C).

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FIG. 2. Reduction of infectious virus in CRL-IKK EE cells is due to IFN- ${alpha}$ /ß. CRL cells (A) and Vero cells (B) were infected with BDV (MOI = 0.01) and cultured for 6 days. Thereafter, the cells were harvested and the infectivity of 2 x 10⁶ cells/ml was determined by a standard focus-forming assay. (C) Inhibition of BDV by IFN- ${alpha}$ /ß. CRL cells were infected with BDV (MOI = 0.1) and at 3 days p.i. were treated with either 100, 10, or 1 U of human IFN- ${alpha}$ /ß. After 6 days of cultivation, the cells were harvested and the BDV infectivity was estimated by a standard focus-forming assay. The bars represent averages and standard deviations of three independent virus titrations.

Electrophoretic mobility shift assay revealed no activation of NF- ${kappa}$ B by BDV. To analyze whether BDV as an RNA virus interferes with the IKK/NF- ${kappa}$ Bsignaling cascade, we infected the CRL-IKK/I ${kappa}$ B mutant cell lineswith BDV (MOI = 1) for 6 days. Thereafter, the cells were harvestedand the nuclei were isolated and screened in an EMSA for DNAbinding activity of activated NF- ${kappa}$ B as described in Materialsand Methods. As shown in Fig. 3A, neither CRL-VEC cells thatfunctioned as a negative control nor CRL-IKK EE, CRL-IKK KD,or CRL-mI ${kappa}$ B ${alpha}$ cells showed NF- ${kappa}$ B binding after BDV infection. Incontrast, when cells were stimulated with TPA, NF- ${kappa}$ B bindingwas found for CRL-VEC and CRL-IKK EE cells. In addition, NF- ${kappa}$ Bactivation in CRL-IKK KD cells was reduced compared to thatin CRL-VEC and CRL-IKK EE cells, while in CRL-mI ${kappa}$ B ${alpha}$ cells, TPAwas unable to stimulate NF- ${kappa}$ B (Fig. 3A).

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FIG. 3. Lack of NF- ${kappa}$ B activation after BDV infection. For EMSAs, IKK/I ${kappa}$ B mutant CRL cells were infected with BDV (MOI = 1) on day 0 or left uninfected, and the cells were stimulated with TPA (0.3 µg/ml) for 40 min on day 6 p.i. Thereafter, nuclear extracts were isolated and incubated with ³²P-labeled double-stranded oligonucleotides specific for NF- ${kappa}$ B (A) or IRF-3/7 (B). The samples were then separated in nondenaturing 5% polyacrylamide gels. After drying, the gels were subjected to autoradiography. (C) NF- ${kappa}$ B-luciferase reporter gene assay. Stably transfected CRL-VEC or CRL-IKK EE cells were infected with BDV (MOI = 1), and 6 days later, these BDV-infected cells together with uninfected cells were seeded into 24-well plates and transfected with a luciferase reporter gene plasmid driven by a 3x ${kappa}$ B binding site containing an artificial promoter on the following day. Six hours after transfection, uninfected cells and individual samples of BDV-infected cells were treated with 0.3 µg/ml TPA and harvested 16 h later for luciferase assays. The bars represent averages and standard deviations of three independent transfections.

Besides the viral activation of NF- ${kappa}$ B, the activation of IRF-3/7is another hallmark of an efficient antiviral response leadingto IFN- ${alpha}$ /ß production. Therefore, the binding of IRFsto the PRI/III region of the IFN-ß promoter, the sequenceto which IRF-3 and -7 bind, was investigated during BDV infection.No specific IRF-DNA binding was observed for wild-type CRL cells(Wt) or CRL-VEC cells up to 120 h postinfection (p.i.). In contrast,specific PRI/III binding complexes were found for BDV-infectedCRL-IKK EE cells at 96 h p.i. and were more pronounced 120 hafter infection. To verify the specificity of binding, we coincubatedsamples with unlabeled competitive PRI/III specific probes attwo different concentrations (1:100 and 1:10). Consequently,the IRF-specific oligonucleotide complex disappeared due tocompetition (Fig. 3B, right end).

Furthermore, we investigated whether BDV infection leads tothe activation of NF- ${kappa}$ B transcriptional activity in an NF- ${kappa}$ B promoter-dependentreporter gene assay. In this case, TPA stimulation of CRL-VECor CRL-IKK EE cells resulted in NF- ${kappa}$ B activation (Fig. 3C). Incontrast, BDV infection of CRL-VEC or CRL-IKK EE cells did notresult in NF- ${kappa}$ B-dependent transcription activity. More surprisingly,even the activation of BDV-infected CRL-VEC or CRL-IKK EE cellswith TPA did not result in an increase in NF- ${kappa}$ B activity comparedto control cells (Fig. 3C). This might suggest that BDV inhibitsNF- ${kappa}$ B activation with a block that cannot be overcome by TPAstimulation.

Distribution of active NF- ${kappa}$ B and BDV infectivity in the rat brain. Activated NF- ${kappa}$ B, defined by immunohistological staining usinga phospho-specific antibody directed against the p65 subunit,is regularly found in cells of the normal rat brain (28). Dependingon the rat strain, phosphorylated p65 can be detected eitherin the hippocampus or in the cortex. In the Lewis rat, NF- ${kappa}$ Bactivity is more pronounced in the cortex, but a few neuronswith activated NF- ${kappa}$ B are also detectable in the hippocampus (28).After BDV infection of Lewis rats with a rat-adapted virus strain,BDV was first detected in the hippocampus. During infection,the virus spread to the cortex and the cerebellum. By day 21p.i., BDV-infected cells could be found in almost all compartmentsof the brain. When the distributions of activated NF- ${kappa}$ B and aBDV-specific nucleoprotein were compared, it was obvious thatin the early phase of the disease, between day 12 and day 15p.i., BDV was found in areas where activated NF- ${kappa}$ B was almostabsent. As shown in Fig. 4A and B, phospho-p65-specific stainingwas predominantly found in an area of the cortex. In the sameregion considerably less BDV antigen was detectable, as demonstratedby the use of serial brain sections; in contrast, BDV was foundin a region closely adjacent to areas with activated NF- ${kappa}$ B (Fig.4C and D). The observation that BDV was almost absent in areaswith NF- ${kappa}$ B activity was supported by the distribution of BDVin Purkinje cells of the cerebellum. When we investigated serialbrain sections for the presence of BDV and activated NF- ${kappa}$ B, wepredominately found BDV infection only in Purkinje cells inwhich NF- ${kappa}$ B was not activated (Fig. 4E and F).

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FIG. 4. Immunohistochemistry revealed different distributions of NF- ${kappa}$ B and BDV in the rat brain. Brain samples were obtained at different time points after infection and were fixed in 4% paraformaldehyde. (A) Distribution of activated NF- ${kappa}$ B in the cortex of a BDV-infected rat brain (18 days p.i.) detected with the pNF- ${kappa}$ B p65-specific rabbit antibody. Magnification, x10. (B) Same section as panel A. Magnification, x20. (C) Distribution of BDV in the cortex of a rat brain (18 days p.i.) detected with an anti-nucleoprotein mouse monoclonal antibody (38/17C1).Magnification, x10. (D) Same section as panel C. Magnification, x20. (G) NF- ${kappa}$ B staining of the hippocampus (day 12 p.i.). Magnification, x10. (H) The serial section shown in panel E was used for BDV staining of the hippocampus (day 12 p.i.). Magnification, x10. (E) NF- ${kappa}$ B p65 staining in the cerebellum at 18 days p.i. Magnification, x40. (F) Detection of BDV nucleoprotein in the cerebellum 18 days after BDV infection. Magnification, x40. Arrows indicate Purkinje cells. The staining reaction was enhanced by the use of a biotinylated secondary antibody. For detection, an ABC kit was used.

In contrast, in the entire hippocampal area only a few cellswere found to be positively stained for phospho-p65 (Fig. 4G)by day 12 p.i., whereas the BDV antigen could easily be detectedin large amounts, mostly in the CA3 region of the hippocampus(Fig. 4H). Most interestingly, not only was the number of cellsthat were positive for activated NF- ${kappa}$ B in the hippocampus differentfrom that in the cortex, but also the distribution of NF- ${kappa}$ B withinthe cell differed. In the hippocampus, phospho-p65-specificsignals were predominately found punctually around the nuclei(Fig. 5A), while in the cortex the nuclei of the neuronal cellswere fully stained (Fig. 5B). At later time points after BDVinfection, activation of NF- ${kappa}$ B in the hippocampus was found,as exemplified on day 18 p.i. (Fig. 5C). Thus, during the earlyphase of the disease, BDV prefers areas where activated NF- ${kappa}$ Bis less dominant or even absent, whereas later during infectionactivated NF- ${kappa}$ B and BDV are both found in conjunction throughoutthe brain.

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FIG. 5. Activation of NF- ${kappa}$ B in the hippocampus late after BDV infection. Brain samples were fixed in 4% paraformaldehyde. (A) Perinuclear p65 staining in the hippocampus, as detected with the pNF- ${kappa}$ B p65-specific rabbit antibody. Magnification, x40. (B) Nuclear staining of p65 in cells of the cortex. Magnification, x20. (C) Nuclear staining of p65 in cells of the hippocampus 18 days after BDV infection. Magnification, x20. Arrows indicate areas of enlargement. The staining reaction was enhanced by the use of a biotinylated secondary antibody. For detection, an ABC kit was used.

DISCUSSION

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Discussion

A wide variety of viruses activate the transcription factorNF- ${kappa}$ B. Although this transcription factor may support the replicationof some of these viruses (e.g., retroviruses or oncogenic viruses)(23), in general RNA virus-mediated NF- ${kappa}$ B activation appearsto act antivirally. Infections with these viruses commonly resultin the activation of an innate antiviral response mediated byIFN- ${alpha}$ /ß. The antiviral activity of the host cell isinitiated by immediate viral induction of the IFN-ßgene. This process requires the cooperative activation of severaltranscription factors, namely, AP-1, IRF-3, IRF-7, and NF- ${kappa}$ B(11). The constitutively expressed IRF-3 protein and the induciblefactor IRF-7 are the critical transcription factors requiredfor virus-induced IFN production. IRF-3 resides in the cytoplasmin a latent form and translocates to the nucleus upon viralinfection and in response to dsRNA (reviewed in reference 54).Recently, it was demonstrated that IKK ${varepsilon}$ /TBK-1, an IKK-relatedkinase, is responsible for IRF-3 and IRF-7 phosphorylation (15,49).

BDV is a nonsegmented RNA virus whose replication occurs inthe nuclei of infected cells. BDV leads to a persistent infectionin vitro and in vivo. In the present study, we demonstratedthat BDV infections of highly susceptible CRL cells did notinduce NF- ${kappa}$ B or IRF-3/7 activation. Only in CRL cells with constitutivelyactivated IKK did BDV infection lead to the translocation andconsequently activation of IRFs as late as 96 h p.i., becomingmore pronounced 120 h after infection. This late activationof IRFs by BDV is not surprising since BDV replication is ratherslow (8). The fact that IRF activation was not found in CRLcells after BDV infection was more surprising. Recently, itwas shown that the NS3/A4 viral protease of hepatitis C virusis able to suppress IRF-3 activation and consequently promotehepatitis C virus replication (16). Whether a similar mechanismis used by BDV cannot be determined since no protein with asimilar activity to that of NS3/A4 has been identified for BDVso far. We were also unable to find an activation of NF- ${kappa}$ B afterBDV infections of CRL cells. Even the costimulation of BDV-infectedcells with TPA did not cause the NF- ${kappa}$ B activity levels seen inCRL-VEC or CRL-IKK EE cells that were stimulated with TPA alone.Thus, it seems that a viral compound might be responsible forcausing inhibition of the activation of NF- ${kappa}$ B that cannot beovercome with TPA, a potent NF- ${kappa}$ B activator.

Again, the question rises as to whether BDV fails to activateNF- ${kappa}$ B or has an active inhibitory effect on NF- ${kappa}$ B/IRF activation.Recently, it was shown that IKK ${varepsilon}$ and TBK-1 are responsible forthe coordination of IRF-3/NF- ${kappa}$ B activation (15). It has beenproposed that Toll-like receptor 3 (TLR3) recognizes dsRNA providedthrough viral infection (1). TLR3 can stimulate a multicomponentprotein complex that activates IKK ${varepsilon}$ and TBK-1 (15). Thus, onemight argue that BDV actively inhibits the IRF/NF- ${kappa}$ B activationthat is performed by viral interference within this regulatoryprotein complex. This hypothesis is supported by the fact thatIRF activation and IFN production are indeed found in BDV-infectedCRL-IKK EE cells. Since IKK ${varepsilon}$ and TBK-1 synergize with TANK (TRAFfamily member-associated NF- ${kappa}$ B activator) to promote an interactionwith IKK- ${gamma}$ of the IKK signalosome complex (10), the constitutiveactivation of IKK could provide an appropriate amount of theTANK/IKK ${varepsilon}$ /TBK-1 complex required for IRF activation. As a possibleresult of this activation, which leads to IFN- ${alpha}$ /ß production,BDV replication was reduced in BDV-infected CRL-IKK EE cellsand IFN was detectable exclusively in CRL-IKK EE cells, notin CRL-VEC, CRL-IKK KD, or CRL-mI ${kappa}$ B ${alpha}$ cells. Since the amount ofIFN was low in the supernatants of CRL-IKK EE cells, one mightargue that a second signal other than NF- ${kappa}$ B is required for IFNactivation. In contrast, when Vero mutant cell lines were usedfor BDV infection, no inhibition of BDV replication was found,even in Vero-IKK EE mutant cells. Since Vero cells have a geneticdefect in interferon production (14), Vero-IKK EE cells arenot able to produce IFN even after BDV infection. When IFN- ${alpha}$ /ßwas added to either CRL cells (Fig. 2C) or Vero cells (20),BDV replication was efficiently blocked, indicating that BDVreplication in general is susceptible to IFN (56). This is furthersupported by the fact that BDV can replicate in cultured embryocells of IFN- ${alpha}$ /ß knockout mice but not in wild-typecontrol cells (50). Nevertheless, in this respect the in vivosituation might be rather different. For example, IFN- ${alpha}$ can bedemonstrated by reverse transcription-PCR to be present in thebrains of normal rats, and IFN- ${alpha}$ -specific mRNA does not significantlyincrease during persistent BDV infection (48). Since reversetranscription-PCR cannot distinguish between different brainareas, the question of whether during the early phase of BDVinfection the virus is only found in areas where IFN- ${alpha}$ is notpresent or if in vivo the effectiveness of IFN- ${alpha}$ is limited stillremains unanswered.

To address the possible in vivo relevance of our in vitro findings,we infected adult Lewis rats with BDV. The distribution andcorrelation of BDV with NF- ${kappa}$ B activation were examined by immunohistochemistry.Activation of NF- ${kappa}$ B was detected with an antibody directed againstthe phosphorylated p65 (RelA) subunit of the dimeric NF- ${kappa}$ B transcriptionfactor. Active NF- ${kappa}$ B was found in the cerebral cortex, and toa lesser extent, in the hippocampus of the normal rat brain.Activation of the transcription factor NF- ${kappa}$ B plays a criticalrole in preventing neuronal cell death (53, 60). In contrast,the inhibition of NF- ${kappa}$ B promotes apoptosis in neurons (17, 27).Consequently, activated NF- ${kappa}$ B seems to participate in normalrat brain functioning, reflecting a distinct state of neuronalactivity or differentiation (28). At early time points afterBDV infection, BDV spread to regions where NF- ${kappa}$ B was not activated.During the peak of BDV infection, between days 18 and 21 p.i.,cells expressing viral antigens were found in the hippocampusand the cortex and also to a lesser extent in the cerebellum.At this time point, the activation of NF- ${kappa}$ B was increased, mostprobably due to the presence of cytokines that promote NF- ${kappa}$ Bactivation in BDV-infected rat brains (34, 42, 45, 48). Thefact that NF- ${kappa}$ B promotes neuronal activity or differentiationseems contradictory to the biology of BDV. Recently, we reportedthat BDV prefers slow proliferative host cells and that BDVis able to reduce the host cell cycle by interfering with theCdc2/cyclin B1 complex (38). Therefore, it is tempting to speculatethat BDV avoids the infection of neurons with active NF- ${kappa}$ B duringthe early phase of infection to ensure effective virus spreadand, most obviously, viral persistence. In contrast, at thepeak of BDV infection, at about day 21 p.i., BDV infectivityand NF- ${kappa}$ B activity were found in the same regions of the brain,indicating that the inhibitory effect of BDV on NF- ${kappa}$ B activitycan be overcome in vivo, most probably due to the activationof various cytokines that function as potent NF- ${kappa}$ B activatorsin the brain, such as interleukin-1 (38).

In summary, these findings demonstrate that after BDV infection,the hallmark transcription factors IRF and NF- ${kappa}$ B that are necessaryfor the expression of various genes involved in the innate immuneresponse of the virus-infected cell are not activated in CRLcells. Whether this is due to active inhibition by the virusitself and if this observation can be generalized cannot beanswered yet. Our in vivo findings for BDV-infected rats showa negative correlation between the activation of NF- ${kappa}$ B and viralreplication, and we therefore propose that nonactive IRF-3/NF- ${kappa}$ Bis a prerequisite for the establishment of a persistent infectionboth in vitro and in vivo.

ACKNOWLEDGMENTS

We thank Lothar Stitz for a critical reading of the manuscriptand for helpful discussions. Furthermore, we thank WinfriedKramer and Mandy Laukner for technical assistance.

This study was supported in part by grants Pla 256/1-2 and WO554/2-1 of the Deutsche Forschungsgemeinschaft and by grant729.59-8/1 of the Forschungsprogramm Baden-Württemberg.Furthermore, this work is part of the activities of the VIRGILEuropean Network of Exellence on Antiviral Drug Resistance supportedby a grant (LSHM-CT-2004-503359) from the Priority 1 "Life Sciences,Genomics and Biotechnology for Health" programme in the 6thFramework Programme of the EU.

FOOTNOTES

* Corresponding author. Mailing address: Institut für Immunologie, Friedrich Loeffler Institut, Bundesforschungsinstitut für Tiergesundheit, Paul Ehrlich Str. 28, 72076 Tübingen, Germany. Phone: 49 7071 967 254. Fax: 49 7071 967 105. E-mail: oliver.planz{at}tue.bfav.de.

REFERENCES

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