The Lytic Cycle of Epstein-Barr Virus Is Associated with Decreased Expression of Cell Surface Major Histocompatibility Complex Class I and Class II Molecules

Human herpesviruses utilize an impressive range of strategiesto evade the immune system during their lytic replicative cycle,including reducing the expression of cell surface major histocompatibilitycomplex (MHC) and immunostimulatory molecules required for recognitionand lysis by virus-specific cytotoxic T cells. Study of possibleimmune evasion strategies by Epstein-Barr virus (EBV) in lyticallyinfected cells has been hampered by the lack of an appropriatepermissive culture model. Using two-color immunofluorescencestaining of cell surface antigens and EBV-encoded lytic cycleantigens, we examined EBV-transformed B-cell lines in whicha small subpopulation of cells had spontaneously entered thelytic cycle. Cells in the lytic cycle showed a four- to fivefolddecrease in cell surface expression of MHC class I moleculesrelative to that in latently infected cells. Expression of MHCclass II molecules, CD40, and CD54 was reduced by 40 to 50%on cells in the lytic cycle, while no decrease was observedin cell surface expression of CD19, CD80, and CD86. Downregulationof MHC class I expression was found to be an early-lytic-cycleevent, since it was observed when progress through late lyticcycle was blocked by treatment with acyclovir. The immediate-earlytransactivator of the EBV lytic cycle, BZLF1, did not directlyaffect expression of MHC class I molecules. However, BZLF1 completelyinhibited the upregulation of MHC class I expression mediatedby the EBV cell-transforming protein, LMP1. This novel functionof BZLF1 elucidates the paradox of how MHC class I expressioncan be downregulated when LMP1, which upregulates MHC classI expression in latent infection, remains expressed in the lyticcycle.

INTRODUCTION

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Introduction

Epstein-Barr virus (EBV) is a ubiquitous gammaherpesvirus foundin more than 90% of adults in all populations worldwide. Followingprimary infection in immunocompetent individuals, the virusgenerally establishes lifelong persistence in B lymphocytes.Most EBV-infected B cells in the healthy host show a restingphenotype with very limited expression of the viral genome (34,41, 58). However, expression of a broader panel of 11 "latent"viral genes leads to growth transformation of B cells (26, 27).This growth transformation is thought to be a mechanism forexpansion of the pool of EBV in the infected host. In addition,the lytic replicative cycle, which produces infectious virions,is likely to be important for periodic expansion of the poolof virus-infected cells within the host and for horizontal transmissionof the virus. Latently infected, growth-transformed B-lymphoblastoidcells are good targets for EBV-specific cytotoxic T lymphocytes(CTL). This limits the potentially pathogenic consequences ofuncontrolled proliferation of virus-infected cells (43). Itis unclear whether lytically infected cells are subjected tothe same immune controls.

CD8⁺ CTL are a major line of defense in the immune responseto viral infection (23, 43, 44). The T-cell receptors on virus-specificCTL interact with major histocompatibility complex (MHC) classI molecules presenting viral peptides on the surface of theinfected cell. Presentation of viral peptides involves severalcomponents of the endogenous antigen-processing pathway, includingcleavage of antigen by proteasomes, translocation of peptidesinto the lumen of the endoplasmic reticulum (ER) by the transporterassociated with antigen processing (TAP), and loading onto heterodimersof newly synthesized MHC class I heavy chain and ß₂-microglobulin.This stabilized trimeric complex is then transported to theplasma membrane (33, 40). In EBV-transformed lymphoblastoidcells, the virally encoded latent membrane protein-1 (LMP1)enhances antigen-processing functions at several levels. LMP1alters proteasome subunit expression and upregulates expressionof TAP subunit proteins, MHC class I and class II molecules(51, 62), and cell surface adhesion molecules (20, 59). Conversely,the EBNA1 protein of EBV contains an unusual glycine-alaninerepeat sequence which, while not interfering with antigen processingof other viral and cell genes, prevents processing of antigenicEBNA1 peptides and their presentation to CTL (29).

While it is crucial for the host-virus relationship that proliferationof growth-transformed EBV-infected B cells be controlled byvirus-specific CTL immunosurveillance, efficient virus productionin the lytic cycle would benefit from effective evasion of CTLresponses. As reviewed elsewhere (5, 23, 40), the alpha- andbetaherpesviruses utilize numerous immune evasion strategiesin order to achieve persistence, and with rare exceptions, theviral genes demonstrated to interfere with immune recognitionare expressed during the lytic cycle of these herpesviruses.Only recently have analogous immune evasion strategies beendescribed for gammaherpesviruses. Thus, Kaposi's sarcoma-associatedherpesvirus (also known as human herpesvirus 8) contains twoopen reading frames (ORFs) whose gene products, K3 and K5, havethe ability to interfere with the cell surface expression ofMHC class I molecules (22, 25, 37). A related K3 ORF in themurine gammaherpesvirus 68 has also been shown to downregulatecell surface MHC class I expression and to inhibit antigen presentation(56). To date, no such immune evasion strategy has been identifiedin the lytic program of EBV. Indeed, since the transformation-associatedLMP1 gene is expressed throughout the EBV lytic cycle in B cells(52), it is possible that MHC expression and antigen presentationfunctions would remain enhanced.

Study of EBV lytic infection is difficult due to the lack ofa fully permissive culture system for the virus (27). NormalB cells transformed in vitro with EBV give rise to lymphoblastoidcell lines (LCL) displaying a latency III type of infection,in which about 11 transformation-associated genes are expressed.Some EBV-positive Burkitt's lymphoma (BL) lines showing a morerestricted, latency I pattern of EBV latent gene expressioncan be induced into the lytic cycle with variable efficiency(typically 5 to 40% of cells enter the lytic cycle) by activationwith chemical inducers, such as phorbol esters or n-butyrate,or by ligation of surface immunoglobulin (12, 52, 57). However,these BL models are not helpful in the present context since,unlike LCL and BL lines with a latency III pattern of gene expression,latency I BL lines already have impaired antigen-processingfunctions (51). Therefore, we have taken advantage of the factthat some latency III BL lines and LCL consistently show a smallproportion of cells, typically less than 5%, which have spontaneouslyentered the lytic cycle (27).

Isolation of the subpopulation of cells in the lytic cycle,using immunosorting strategies targeting a cell surface markerof the lytic cycle, would enable biochemical and functionalstudies. Unfortunately, this option is ruled out by the factthat lytic-cycle genes expressed at the cell surface (e.g.,gp340) are also present on infectious viruses; the EBV releasedfrom lytic cells can bind neighboring latently infected cellsexpressing the CD21 receptor for the virus, thereby creatinga large percentage of gp340⁺ cells which are not actually inthe lytic cycle (14). We therefore developed a dichromatic flowcytometry assay to stain for surface cellular antigens on viablecells, followed by fixation, permeabilization, and intracellularstaining of the EBV immediate-early lytic antigen, BZLF1, orthe late viral capsid antigen (VCA). This allowed us to analyzecellular gene expression in lytic EBV infection compared tothat in latent infection in the same culture. The results showedEBV lytic infection to be associated with a substantial reductionin cell surface MHC class I expression and a smaller, but significant,reduction in MHC class II expression. These observations wereparadoxical, since expression of both MHC class I and MHC classII molecules can be upregulated by LMP1 (51, 62), which remainsexpressed during the lytic cycle (52). We therefore investigatedwhether lytic-cycle gene expression might interfere with theability of LMP1 to upregulate MHC expression.

MATERIALS AND METHODS

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Materials and Methods

Cells. Eli-LCL is an EBV-positive LCL derived by infection of normalperipheral blood B cells with the B95.8 strain of EBV (53).Ag876 is an EBV-positive tumor B-cell line derived from a patientwith BL (39). The Eli-LCL and Ag876 lines both display a predominantlylatency III type of infection but contain up to 5% BZLF1-positivecells. The EBV-positive P3HR-1-c16 cell line is a strictly nonproducingsubclone of the P3HR-1 mutant BL line (42), which can be inducedinto the lytic cycle by treatment with n-butyrate and phorbolesters. A deletion in the EBV genome of P3HR-1 removes the EBNA2gene, and the loss of this transactivator results in downregulationof LMP1 expression in the latent infection state (1, 48). DG75is an EBV-negative tumor B-cell line derived from a patientwith BL (7). Cell lines were cultured in RPMI 1640 medium supplementedwith 10% fetal calf serum, 2 mM L-glutamine, and antibiotics(200 U of penicillin/ml and 200 mg of streptomycin/ml) and weremaintained at 37°C in a humidified atmosphere containing5% CO₂. Inhibition of viral DNA replication and late-lytic-cyclegene expression was achieved by culturing cells in a culturemedium supplemented with 0.1 mM acyclovir (Sigma) for 2 weeks.

Antibodies. The EE reagent is a human serum from a chronic infectious-mononucleosispatient with unusually high titers of antibodies to lytic-cycleantigens (52). BZ.1 is a murine monoclonal antibody (MAb) tothe immediate-early protein encoded by the BZLF1 ORF (60). MAbL2 recognizes a 125-kDa late-lytic-cycle antigen which is amajor component of the VCA complex (28) and was a kind giftfrom G. Pearson (Georgetown University, Washington, D.C.). CS.1-4is a pool of MAbs to LMP1 (49). OX34, a MAb specific for ratCD2, and W6/32, a MAb specific for MHC class I (HLA-A, -B, and-C alleles), were produced from hybridomas purchased from theAmerican Tissue Culture Collection. MAb Tü149, recognizingMHC class I (HLA-B and -C, and some HLA-A alleles) was kindlyprovided by B. Uchanska-Ziegler (Berlin, Germany). MAb BU.12,specific for CD19, was a kind gift from D. Hardie (Universityof Birmingham, Birmingham, United Kingdom). The murine MAb WR18,specific for MHC class II (DP, DQ, and DR antigens) and thered phycoerythrin (RPE)-conjugated MAbs specific for CD54 andCD40 were purchased from Serotec, Oxford, United Kingdom. MAbsL307.4 (anti-CD80) and FUN-1 (anti-CD86) were purchased fromBD Biosciences Pharmingen.

Biotinylation of antibody BZ.1. Antibody BZ.1 (60) was purified from hybridoma culture supernatantby affinity chromatography with Sepharose-protein A. The purifiedantibody was biotinylated by using the Immunoprobe Biotinylationkit (Sigma) according to the manufacturer's instructions.

Flow cytometry analysis of BZLF1 and VCA expression. Cells were fixed and permeabilized to allow for detection ofthe intracellular markers of the EBV lytic cycle by indirectimmunofluorescence. This was achieved by incubating the cellswith a 2% paraformaldehyde solution in phosphate-buffered saline(PBS) for 30 min on ice, followed by incubation with 0.2% TritonX-100 for 30 min on ice. After extensive washes in PBS, cellswere incubated either with 1 µg of MAb BZ.1 (anti-BZLF1)/mlor with 1/1,000-diluted L2 ascites fluids (anti-VCA) for 1 hat 37°C. Cells were washed twice in PBS and incubated with1:50-diluted fluorescein isothiocyanate (FITC)-conjugated goatanti-mouse immunoglobulin G (IgG; Sigma) for 1 h at 37°C.After further washes, cells were resuspended in 2% paraformaldehydeand analyzed on a FACScalibur flow cytometer (Becton DickinsonCo., San Jose, Calif.).

Flow cytometry analysis of cell surface antigen expression in BZLF1- and VCA-positive cells. Cell surface antigen and intracellular EBV lytic-cycle antigenswere detected simultaneously by first staining viable cellswith an antibody specific for cell surface protein detectedwith RPE-conjugated antibodies, then fixing and permeabilizingthe cells (see above), and staining for intracellular antigendetected with FITC-conjugated antibodies. Optimal two-colorstaining of surface MHC class I molecules and intracellularBZLF1 or VCA was achieved by staining viable cells with 5 µgof W6/32 (IgG2a MAb)/ml for 30 min at 4°C, fixing and permeabilizing,and then staining with 1 µg of BZ.1 (IgG1 MAb to BZLF1)/mlor 1:1,000-diluted L2 (IgG1 MAb to VCA) for 1 h at 37°C.The two primary antibodies were subsequently detected by incubationfor 1 h at 37°C with a mixture of RPE-conjugated goat anti-mouseIgG2a antibodies (diluted 1:50; Serotec) and FITC-conjugatedgoat anti-mouse IgG1 antibodies (diluted 1:50; Serotec).

For MAbs used in cell surface staining which, like antibodyBZ.1 against BZLF1, belonged to the IgG1 isotype, the procedurewas modified to allow specific simultaneous detection of cellsurface and intracellular antibody staining. Prior to fixationand permeabilization, the MAb bound to the cell surface wasfirst detected with RPE-conjugated rabbit anti-mouse IgG (diluted1:50; Serotec) and then free binding sites of the secondaryantibody were blocked by incubation for 20 min at room temperaturewith 20% whole mouse serum (The Binding Site, Birmingham, UnitedKingdom) in PBS. Following fixation and permeabilization, cellswere incubated with 1 µg of biotinylated MAb BZ.1/ml followedby incubation with a 1/20 dilution of streptavidin-FITC (SouthernBiotechnology Associates Inc., Birmingham, Ala.) in PBS for25 min at room temperature. In some experiments, primary antibodiesdirectly conjugated with RPE were used (e.g., anti-CD40-RPEand anti-CD54-RPE); in these cases, the incubation steps withsecondary RPE-conjugated anti-mouse IgG1 and with blocking mouseserum were omitted.

Plasmids. Plasmid pSG5-LMP1 expresses wild-type LMP1 cDNA derived fromthe B95.8 strain of EBV (24). The pCMV-I ${kappa}$ B ${alpha}$ ${Delta}$ N plasmid expressesa phosphorylation-defective mutant I ${kappa}$ B ${alpha}$ and was kindly providedby Dean W. Ballard (Howard Hughes Medical Institute, Nashville,Tenn.). The pSG5-trCD2 plasmid expresses a C terminus-truncatedrat CD2 and has been described previously (19). The green fluorescentprotein (GFP) expression vector pEGFP-N1 was purchased fromClontech. The NF- ${kappa}$ B luciferase reporter 3Enh. ${kappa}$ B-ConALuc (3Enh-Luc)contains three tandem repeats of the NF- ${kappa}$ B binding sites fromthe Ig ${kappa}$ promoter upstream of a minimal conalbumin promoter andhas been described previously (6). Plasmid p509, a pCMV-1-basedplasmid that expresses the BZLF1 transactivator of the EBV lyticcycle (46), was obtained from A. Rickinson (Birmingham University).

Gene transfection and luciferase reporter assay. Electroporation of 10⁷ cells in 0.5 ml of RPMI medium was performedby using a Bio-Rad Genepulser II electroporator set to 270 Vand 950 µF for DG75 cells, or 240 V and 950 µF forP3HR1-c16 cells. The cells were then seeded in 4 ml of freshgrowth medium and cultured under normal conditions. Transfectionefficiency was typically 30 to 40% for the DG75 cell line and10 to 15% for the P3HR1-c16 cell line, as determined by transfectionwith pEGFP-N1 and flow cytometry analysis of GFP expression.Luciferase activity from the 3Enh-Luc reporter plasmid was measured24 h after transfection, exactly as described previously (32).

Immunomagnetic separation. Following transfection with pSG5-rCD2, cells expressing ratCD2 were labeled by staining with the rat CD2-specific MAb OX34followed by FITC-conjugated anti-mouse IgG2a antibodies. Thesecells were positively selected by using magnetic cell sortinganti-FITC microbeads and MS columns (Miltenyi Biotech) accordingto the manufacturer's guidelines. More than 90% sort puritywas achieved for transfected P3HR-1-c16 cells.

Detection of lytic-cycle antigens and LMP1 by immunoblotting. Sodium dodecyl sulfate (SDS)-polyacrylamide gel electrophoresisand immunoblotting were performed as described previously (50).Briefly, cells were solubilized by sonication in reducing gelsample buffer, and solubilized proteins equivalent to 2 x 10⁵cells were separated by SDS-polyacrylamide gel electrophoresisand transferred to polyvinylidene difluoride membranes (AmershamLife Sciences) for immunoblotting. Lytic-cycle antigens weredetected by incubating the membranes for 1 h with a 1/10,000dilution of EE human serum followed by incubation for 1 h witha 1/10,000 dilution of alkaline phosphatase-conjugated goatanti-human IgG (Bio-Rad). LMP1 was detected by using 1 µgof MAbs CS.1-4/ml followed by a 1/10,000 dilution of alkalinephosphatase-conjugated goat anti-mouse IgG (Bio-Rad). Boundalkaline phosphatase was developed by using the CDP-Star (TropixInc.) chemiluminescent reagent.

RESULTS

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Results

Cell surface MHC class I expression is decreased in the lytic cycle. In order to analyze the cell surface phenotype of EBV lyticcells, we performed two-color flow cytometry assays to detectcell surface antigens simultaneously with the immediate-earlylytic-cycle nuclear antigen BZLF1. Figure 1A shows results ofa representative experiment with the latency III BL cell lineAg876, in which 1.5% of cells stained positive with MAb BZ.1against BZLF1, detected with FITC-conjugated anti-IgG1 secondaryantibodies. Simultaneous detection of cell surface MHC classI molecules with antibody W6/32 to HLA-A, -B, and -C, followedby RPE-conjugated anti-IgG2a secondary antibodies, revealeda 4.8-fold reduction in the fluorescence intensity of MHC classI molecules staining on BZLF1⁺ cells (mean fluorescence intensity[MFI], 5) relative to that on latently infected, BZLF1^- cells(MFI, 24). Similar results were obtained with a normal EBV-transformedLCL, Eli-LCL. Thus, Fig. 1B shows results of one representativeexperiment with Eli-LCL where 1.7% of cells were BZLF1⁺, andsimultaneous staining with antibody W6/32 revealed a 3.5-foldreduction in the level of MHC class I molecules on the surfacesof BZLF1⁺ cells (MFI, 8) relative to the level on latently infected,BZLF1^- cells (MFI, 28).

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FIG. 1. Downregulation of MHC class I expression in EBV lytic infection. (A) Surface expression of MHC class I molecules on the latency III and lytic EBV-positive BL cell line Ag876. Viable cells were stained with antibody W6/32 (IgG2a isotype, anti-HLA-A, -B, and-C) and then fixed and permeabilized to allow staining with antibody BZ.1 (IgG1 isotype, anti-BZLF1 immediate-early EBV antigen), followed by detection with a pool of FITC-conjugated anti-IgG1 and RPE-conjugated anti-IgG2a secondary antibodies. The left-hand panel is a dot plot of the flow cytometry results of RPE staining (surface MHC class I molecules) (y axis) and FITC staining (nuclear BZLF1) (x axis). The right-hand panel is a histogram of the RPE staining (surface MHC class I molecules) of the latent, BZLF1^- population (light shading) and the lytic, BZLF1⁺ population (dark shading). The MFI of surface MHC class I expression on the latent, BZLF1^- cells is 24, whereas the corresponding MFI for the lytic, BZLF1⁺ cell population is 5. Results shown are representative of four independent experiments. (B) Surface expression of MHC class I molecules on the normal EBV-transformed LCL Eli-LCL. Immunofluorescence staining and analysis were performed exactly as for the Ag876 cells in panel A. In this representative experiment, the MFI of surface MHC class I expression obtained for the latent, BZLF1^- cells was 28, and the corresponding MFI for the lytic, BZLF1⁺ cells was 8.

Next, we examined whether expression of other cellular proteinswas similarly modulated in the lytic cycle. Figure 2 shows representativeresults obtained with the Ag876 BL cell line simultaneouslystained for nuclear BZLF1 and each of the indicated cell surfaceantigens. The pooled results of at least three experiments aresummarized in Fig. 3. Although not as severe as for MHC classI molecules, BZLF1⁺ cells expressed reduced levels of surfaceMHC class II molecules, ranging from 40 to 50% of levels inlatent cells. Furthermore, CD40 and ICAM-1 (CD54) expressionwas reduced by as much as 40% on cells in the lytic cycle. Incontrast, cell surface CD19 expression showed a small increase(18%) on BZLF1⁺ cells, but this did not reach statistical significance(P = 0.2132 by a paired Student t test). Small differences werealso observed in the levels of CD80 and CD86, which are theB7-1 and B7-2 ligands for the CD28 costimulatory receptor onT cells. The 10% decrease in CD80 levels on BZLF1⁺ cells wasnot statistically significant (P = 0.2274), while the 25% increasein CD86 expression did reach statistical significance (P = 0.0298).As shown in Fig. 2, in contrast to all other surface antigensanalyzed, which gave a single, defined population of cells,CD86 staining gave two overlapping populations.

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FIG. 2. Analysis of cell surface protein expression in the lytic cycle. Ag876 cells were stained with antibodies specific for a range of cell surface antigens (for MHC class II, MAb WR18; for CD19, MAb BU.12; for CD40, MAb LOB7/6; for CD54, MAb 15.2; for CD80, MAb L307.4; and for CD86, MAb FUN-1) and labeled with RPE, together with MAb BZ.1 against the BZLF1 immediate-early EBV antigen, labeled with FITC. A representative flow cytometry analysis is shown for each combination of antibodies. Dark shading represents cell surface antigen staining on lytic, BZLF1⁺ cells; light shading represents cell surface antigen staining on latent, BZLF1^- cells; curves defined by dashed lines represent the background RPE fluorescence obtained on cells stained with control antibodies.

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FIG. 3. Summary of the relative levels of cell surface antigen expression on lytic, BZLF1⁺ cells in Ag876 BL cultures. Each result represents the mean relative intensity from at least three separate experiments and is shown as a percentage of the MFI of RPE staining of latently infected cells in the same experiment. Error bars represent the standard errors of the means from at least three separate experiments.

Results similar to those shown in Fig. 2 and 3 were also obtainedwith Eli-LCL. In three separate experiments, the mean MHC classI expression in lytic cells was 29.5% ± 2.93% of expressionin latent cells (P = 0.0321 by a paired Student t test). Insingle experiments, performed in parallel with MHC class I staining,the expression of MHC class II molecules, CD40, and CD54 onlytic cells was reduced to 45 to 50% of that on latent cells,while CD80 and CD86 showed a 15% reduction and a 15% increase,respectively, on lytic cells. Together, these data obtainedwith Ag876 cells and Eli-LCL suggest that the marked reductionin MHC class I expression observed during EBV lytic infectionis unlikely to be the result of a global shutdown in proteinsynthesis.

Downregulation of MHC class I expression is an early event in the lytic program. Because the downregulation of MHC class I expression may beimportant for immune escape from CTL responses, it is of interestto know at what stage in the lytic cycle the expression of MHCclass I molecules is affected. BZLF1 is expressed by cells atboth early and late stages of the lytic cycle. Therefore, ifdownregulation of MHC class I expression were a late-lytic-cycleevent, it is possible that a greater degree of downregulationwould be observed by analyzing only cells expressing a late-lytic-cyclemarker such as VCA. The next set of experiments addressed thisquestion. Figure 4A shows results of a representative two-colorimmunofluorescence experiment with Ag876 cells stained eitherfor MHC class I molecules and BZLF1 (left panel) or for MHCclass I molecules and VCA (right panel). In this experiment,1.5% of cells stained positive for BZLF1 while 0.6% of cellsstained positive for VCA. MHC class I expression was reducedto similar degrees on BZLF1⁺ cells (4.8-fold reduction) andVCA⁺ cells (5-fold reduction) relative to expression in thelatently infected population.

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FIG. 4. Downregulation of MHC class I expression is an early-lytic-cycle event. (A) Surface expression of MHC class I molecules on BZLF1⁺ and VCA⁺ cells in the lytic cycle. Ag876 BL cells were simultaneously stained to detect surface MHC class I expression and intracellular lytic-cycle antigen expression exactly as for Fig. 1. The left-hand flow cytometry dot plot shows staining with MAbs W6/32 (anti-MHC class I; RPE conjugated) (y axis) and BZ.1 (anti-BZLF1; FITC conjugated) (x axis). The right-hand dot plot shows parallel staining of cells with MAb W6/32 (y axis) and L2 (anti-VCA; FITC conjugated) (x axis). (B) Surface expression of MHC class I molecules on acyclovir-treated and untreated Ag876 BL cells. Cells cultured in acyclovir for 2 weeks and replicate untreated cells were simultaneously stained with MAbs W6/32 and BZ.1 exactly as for Fig. 1. Results shown are dot plot flow cytometry profiles of W6/32 staining (RPE conjugated) (y axis) versus BZ.1 staining (FITC conjugated) (x axis) obtained for untreated control cells (left panel) and acyclovir-treated cells (right panel).

The results in Fig. 4A indicate that downregulation of MHC classI expression is an early event in the lytic cascade. To confirmthis, Ag876 cells were cultured in the presence or absence ofacyclovir for 2 weeks. Acyclovir is phosphorylated by EBV-encodedthymidine kinase to generate acyclovir monophosphate and thenby cellular kinases to generate the di- and triphosphate forms.Acyclovir triphospate, an analogue of the nucleoside dGTP, ispreferentially incorporated into growing chains of viral DNA,and it terminates extension of the DNA template. Culturing cellsin acyclovir inhibits lytic viral DNA replication and, hence,expression of late-lytic-cycle antigens (30). Immunofluorescencestaining with an anti-VCA MAb demonstrated that while VCA wasdetected on a subpopulation of control Ag876 cultures, it wasundetectable in cells cultured with acyclovir for 2 weeks (datanot shown). Figure 4B shows the results of two-color flow cytometryanalysis of nuclear BZLF1 and surface MHC class I expressionin control Ag876 cells and acyclovir-treated Ag876 cells. MHCclass I expression was reduced to similar degrees on BZLF1⁺cells in the two cultures. Thus, in the experiment shown, BZLF1⁺cells in control cultures showed a mean intensity of MHC classI staining that was 28.6% of that observed in BZLF1^- cells (a3.5-fold reduction), while BZLF1⁺ cells in acyclovir-treatedcultures showed a mean intensity of MHC class I staining thatwas 29.4% of that observed in BZLF1^- cells (a 3.4-fold reduction).Therefore, downregulation of cell surface MHC class I expressionis initiated during the immediate-early or early phase of thelytic cycle and persists through the late lytic cycle.

LMP1 is expressed in the lytic cycle. In latent infection, LMP1 has been shown to upregulate expressionof MHC class I molecules (51). Investigation of the mechanismof downregulation of MHC class I expression in the lytic cycleneeds to take into consideration the fact that the latent geneproduct, LMP1, is also expressed in the lytic cycle (52). Thus,as illustrated by the results in Fig. 5, when cells with a latencyI type of infection are induced into the lytic cycle, LMP1 expressionis also induced. In this experiment, EBV⁺ P3HR1-c16 cells wereelectroporated with a BZLF1 expression plasmid to initiate thelytic-cycle cascade and with a GFP-rCD2 marker gene to allowimmunosorting of transfected cells expressing cell surface rCD2.At 24 h after transfection, immunoblot analysis was performedon the negative and positive sorted cells with a human serumreactive with several early- and late-lytic-cycle antigens (Fig.5, upper blot). The results confirmed that lytic-cycle antigenexpression was undetectable in untransfected, latently infectedcells, while high levels of expression of early- and late-lytic-cycleantigens were seen in BZLF1-transfected cells. Reprobing theimmunoblot with MAbs CS.1-4 (Fig. 5, lower blot) showed thatLMP1 was undetectable in the latently infected population butwas clearly expressed in the lytic population. We have alsoshown by two-color immunofluorescence that LMP1 remains expressedin cells which spontaneously enter the lytic cycle from a latencyIII type of infection, as in the Ag876 and Eli-LCL lines (M.Rowe, unpublished data). These observations raise the question:why is LMP1 unable to induce or maintain high levels of MHCclass I expression in the lytic cycle? Recently, Dreyfus etal. (13) reported that BZLF1 inactivated the transcription factorNF- ${kappa}$ B in human T cells. Since activation of NF- ${kappa}$ B is a major signalingfunction of LMP1, we examined whether coexpression of BZLF1in the lytic cycle might interfere with the ability of LMP1to upregulate MHC class I expression.

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FIG. 5. LMP1 expression during the lytic cycle. Western blot analysis of LMP1 expression in EBV lytic cycle-positive P3HR1-c16 cells was performed. Cells were cotransfected with 8 µg of a BZLF1 expression plasmid to induce the EBV lytic cycle and with 3 µg of a rat CD2 surface antigen expression plasmid to allow transfected cells to be positively selected by immunomagnetic separation. At 24 h following transfection, viable cells were labeled with OX34 (an anti-rat CD2 MAb) followed by FITC-conjugated anti-IgG; then they were immunomagnetically sorted with anti-FITC MACS microbeads. BZLF1-transfected cells were positively sorted on the basis of rat CD2 expression, while the unbound flowthrough cells were taken to be untransfected, latent cells. Cell samples were analyzed by Western immunoblotting. When probed with EE human serum (top panel), the blot showed staining of BZLF1, early antigens, and late antigens in the positively sorted cells and not in the untransfected, flowthrough cells. Reprobing the blot for LMP1 with MAbs CS.1-4 (lower panel) demonstrated induced expression of LMP1 in the positively sorted, lytically infected cells.

BZLF1 inhibits the ability of LMP1 to upregulate MHC class I expression. The effect of BZLF1 on LMP1-mediated upregulation of MHC classI expression was investigated by cotransfection experimentswith the EBV^- BL line DG75. Replicate cultures of DG75 cellswere transfected either with empty vector DNA or with an LMP1expression plasmid, together with a GFP expression plasmid toserve as a marker of the transfected subpopulation of cells.At 48 h after transfection, MHC class I expression was detectedwith RPE-conjugated antibodies and the intensity of MHC classI expression in the GFP-gated population was analyzed by flowcytometry. The results in Fig. 6A show that expression of LMP1causes a 70% increase in the intensity of MHC class I stainingrelative to that for control cells transfected with empty vectorDNA. Coexpression of BZLF1 with LMP1 completely abolished theability of LMP1 to upregulate MHC class I expression. Thus,Fig. 6A shows that when BZLF1 was cotransfected with LMP1, MHCclass I expression remained at the constitutive level observedin vector control-transfected cells. Coexpression of the NF- ${kappa}$ Binhibitory molecule I ${kappa}$ B ${alpha}$ ${Delta}$ N with LMP1 also had an inhibitory effect,although it was less effective than BZLF1 at inhibiting LMP1-mediatedupregulation of MHC class I expression (Fig. 6A). As shown inFig. 6B, expression of BZLF1 or I ${kappa}$ B ${alpha}$ ${Delta}$ N alone did not affect thelevel of MHC class I expression relative to that for controlcells transfected with empty vector DNA.

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FIG. 6. BZLF1 inhibits LMP1-mediated upregulation of MHC class I expression. (A) Flow cytometric analysis of surface MHC class I expression in LMP1-transfected EBV-negative DG75 cells. Each transfection included 1 µg of the GFP expression vector pEGFP-N1, cotransfected with either 4 µg of pSG5 empty vector DNA, 4 µg of an LMP1 expression plasmid, 4 µg each of an LMP1 expression plasmid and a BZLF1 expression plasmid, or 4 µg each of an LMP1 expression plasmid and an I ${kappa}$ B ${alpha}$ ${Delta}$ N expression plasmid. The total amount of DNA per transfection was kept constant by addition of an appropriate amount of pSG5 empty vector DNA. MHC class I expression was detected 48 h following transfection by staining cells with MAb Tü149 followed by RPE-conjugated anti-IgG antibodies and analyzing by flow cytometry. The MFI of RPE staining (cell surface MHC class I molecules) on the GFP-positive (transfected) viable cell population was quantified. Results shown are means and standard errors from triplicate experiments. (B) Effect of BZLF1 and I ${kappa}$ B ${alpha}$ ${Delta}$ N on constitutive surface MHC class I expression in EBV-negative cells. DG75 cells were cotransfected with 1 µg of a marker plasmid (the GFP expression vector pEGFP-N1) together with 4 µg of either pSG5 empty vector DNA, a BZLF1 expression plasmid, or an I ${kappa}$ B ${alpha}$ ${Delta}$ N expression plasmid. At 48 h following transfection, the cells were stained for MHC class I expression exactly as for Fig. 6A, and the MFI of RPE staining (cell surface MHC class I molecules) on the GFP-positive (transfected) viable cell population was quantified. Results shown are means and standard errors from triplicate experiments.

The inhibitory effect of BZLF1 involves mechanisms in addition to NF- ${kappa}$ B. The results shown in Fig. 6 raise the question of whether BZLF1is in fact mediating its inhibitory effects on LMP1 functionby interfering with activation of NF- ${kappa}$ B. To confirm that BZLF1does inhibit NF- ${kappa}$ B in B cells, we cotransfected DG75 cells withincreasing amounts of a BZLF1 expression vector together witha constant amount of NF- ${kappa}$ B-luciferase reporter DNA. Figure 7Ashows results of a representative experiment in which the highbasal level of NF- ${kappa}$ B activity was inhibited by BZLF1 in a dose-responsivemanner, with a maximum inhibition of 42% at 4 to 6 µgof the BZLF1 expression plasmid. In repeated experiments, inhibitionof 40 to 50% was typically obtained at a dose of 4 µgof transfected BZLF1 plasmid. The inhibition of NF- ${kappa}$ B activityby BZLF1 was never as efficient as the inhibition achieved whenthe NF- ${kappa}$ B reporter plasmid was cotransfected with the I ${kappa}$ B ${alpha}$ ${Delta}$ N expressionplasmid, which typically produced greater than 95% inhibitionof basal NF- ${kappa}$ B activity in DG75 cells (data not shown).

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FIG. 7. Effect of BZLF1 on LMP1-mediated activation of NF- ${kappa}$ B. (A) Dose-dependent inhibition of NF- ${kappa}$ B activation by BZLF1. As much as 6 µg of a BZLF1 expression plasmid was cotransfected with 3 µg of the NF- ${kappa}$ B reporter 3Enh-Luc in DG75 cells. The total amount of DNA per transfection was kept to a constant 9 µg by addition of an appropriate amount of empty vector DNA. Luciferase activity was measured after 24 h. Results shown are means of results from duplicate experiments. (B) Effect of BZLF1 on LMP1-mediated NF- ${kappa}$ B activation. DG75 cells were cotransfected with 3 µg of the NF- ${kappa}$ B reporter 3Enh-Luc together with either 4 µg of pSG5 empty vector DNA, 4 µg of an LMP1 expression plasmid, 4 µg each of an LMP1 expression plasmid and a BZLF1 expression plasmid, or 4 µg each of an LMP1 expression plasmid and an I ${kappa}$ B ${alpha}$ ${Delta}$ N expression plasmid, exactly as for Fig. 6A. The total amount of DNA per transfection was kept constant by addition of an appropriate amount of empty vector DNA. Luciferase activity was measured after 24 h. Results shown are means and standard errors from triplicate experiments.

The effect of BZLF1 on NF- ${kappa}$ B activation in LMP1-transfected cellswas less pronounced. Figure 7B shows results of a representativeNF- ${kappa}$ B reporter experiment that was set up in parallel with thetransfection experiment for which results are shown in Fig.6A. Because of the high basal NF- ${kappa}$ B activity of DG75 cells, expressionof LMP1 results in a modest 2.5-fold increase in reporter activity.However, while coexpression of I ${kappa}$ B ${alpha}$ ${Delta}$ N with LMP1 inhibited NF- ${kappa}$ Breporter activity by 96%, coexpression of BZLF1 with LMP1 inhibitedNF- ${kappa}$ B reporter activity by only 18%. Taken together, the resultsin Fig. 6 and 7 indicate that the ability of BZLF1 to inhibitLMP1-induced MHC class I expression is predominantly mediatedby mechanisms other than the effects of BZLF1 on NF- ${kappa}$ B activation.

DISCUSSION

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Discussion

These experiments show that the cell surface phenotype of cellsspontaneously entering into lytic cycle differs in importantrespects from the surface phenotype of latency III cells inthe same BL or LCL cultures. Cell surface MHC class I expressionwas reduced four- to fivefold from the levels seen on latencyIII cells, while MHC class II expression was reduced twofold(Fig. 3). It has not been possible to test the functional significanceof this reduced MHC expression for recognition by EBV-specificCTL experimentally. Nevertheless, the reduced MHC expressionin the lytic cycle is comparable to the differences betweenlatency I and latency III subclones of EBV-positive BL lines(18, 31, 51), which are sufficient to impair the sensitivityof the BL cells to CTL lysis and to impair their T-cell-stimulatorycapacity in mixed lymphocyte reactions (11, 47, 51). In BL linesdisplaying a latency I pattern of EBV infection, expressionof MHC class I molecules is only one of several components ofthe antigen-processing pathway that appears to contribute toimpaired antigen presentation. It is not known whether the sameis also true of cells in the lytic cycle. However, even a relativelymodest downregulation of MHC class I expression could conceivablyhave a significant effect on antigen presentation if de novoMHC class I synthesis (i.e., those MHC molecules synthesizedafter EBV replication begins) were predominantly inhibited.The 40% reduction seen in CD54 and CD40 expression in the lyticcycle (Fig. 3) could also affect the T-cell-stimulatory capacityof these cells, although it is worth noting that the CD80 andCD86 costimulatory molecules were not substantially affectedby the entry of cells into lytic cycle.

Little is known about presentation of EBV target peptides toCTL during the lytic cycle (44). While CTL responses to severalpeptides of early-lytic-cycle antigens have been demonstrated(9, 38, 55), there have been no reports of recognition and lysisof cells in the lytic cycle by these CTL. In this context, itis of interest that CTL specific for EBNA1 peptides can similarlybe reactivated from the peripheral T cells of infected individuals,even though these EBNA1-specific CTL cannot lyse EBV-transformedB cells expressing EBNA1 (8, 29). Therefore, demonstration ofCTL specific for lytic-cycle antigens is not by itself sufficientto ascertain whether the cells in the lytic cycle are sensitiveto CTL. Addressing this issue directly has been hampered bythe practical problems associated with the lack of a fully permissiveculture model for the EBV lytic cycle (27). Nevertheless, ourpresent study has provided indirect evidence for impaired antigenpresentation in the lytic cycle.

There is one previous report, suggesting that MHC class I andclass II expression may be upregulated in the lytic cycle (12),which contradicts our observations. However, this earlier studyinvestigated the expression of cell surface MHC molecules oncell lines which were induced into lytic cycle by treatmentwith a number of different chemical activators, such as n-butyrateand phorbol esters. Such chemicals have broad effects on cellulargene expression; hence it is difficult to attribute such changesspecifically to induction of the lytic cycle. Indeed, closerinspection of the data published by Di Renzo et al. (12) showsthat MHC expression was elevated not only in the subpopulationof cells in the lytic cycle but also in latently infected cellsin the same culture. In our present study, we avoided the complicationsof chemical induction by examining lines which showed a predominantlatency III type infection but which also contained a subpopulationthat had spontaneously entered into lytic cycle.

Downregulation of surface MHC class I expression is maintainedthroughout the lytic cycle of EBV and can be seen on cells whichhave progressed into late lytic cycle and express VCA (Fig.4A). Because treatment with acyclovir had no effect on the downregulationof MHC class I expression, we concluded that this modulationof MHC expression is an early-lytic-cycle event, occurring inthe immediate-early or early stage of lytic infection, and isnot dependent on the expression of a late-lytic-cycle gene (Fig.4B). It is possible that reduced expression of MHC moleculesis not caused by lytic-cycle genes but that the lytic cycleis preferentially induced in a population of latently infectedcells with a phenotype that includes low expression of MHC molecules.This scenario would not diminish the potential importance ofthe low-MHC-expression phenotype in the lytic cycle with regardto the effect on CTL recognition. Analogy with other herpesviruses,however, favors a scenario where EBV lytic-cycle genes causereduced MHC expression and perhaps also interfere with othercomponents of antigen presentation. Our investigation of thepossible mechanisms of the downregulation of MHC expressionin the lytic cycle focused on two EBV-encoded proteins: (i)BZLF1, since recent evidence points to immunomodulatory functionsfor this immediate-early transactivator protein (see below),and (ii) LMP1, which is expressed as an early-lytic-cycle antigen(52). Since LMP1 is known to upregulate expression of variouscomponents of the antigen-processing pathway (51), we reasonedthat some signaling functions of LMP1 must be impaired in thelytic cycle

The BZLF1 immediate-early transactivator plays an essentialrole in induction of the lytic cycle from latent infection (17,57). BZLF1 is required for expression of many of the early lyticgenes and is also important in mediating viral DNA replicationthrough the lytic origin of replication (15, 16, 54). Thereis increasing evidence suggesting that BZLF1 also interactswith a number of cellular proteins to provide favorable conditionsfor replication. BZLF1 brings about cell cycle arrest throughinduction of cyclin-dependent kinase inhibitors (10, 45). Itcan also alter CREB-binding protein (3, 61) and p53 functions(63), interact with the transcription factor NF- ${kappa}$ B (13, 21),and increase activation of the ATF2 transcription factor (2).While this report was in preparation, BZLF1 was reported toinhibit expression of the gamma interferon receptor (35). Recently,it was also shown that BZLF1 can cause dispersal of nuclearPML bodies and is SUMO-1 modified (4). PML protein appears toplay a role in the regulation of MHC class I presentation andapoptosis (64). Together, these data indicate that BZLF1, inaddition to its essential role in activating the lytic cycle,may have important immunomodulatory functions.

In the present study, we demonstrated that BZLF1 completelyinhibits upregulation of surface MHC class I expression inducedby LMP1 in EBV-negative B cells (Fig. 6A). NF- ${kappa}$ B activation isthought to play a major role in LMP1-mediated upregulation ofsurface MHC class I expression (36), and because there is evidenceto suggest that BZLF1 may interfere with the activation of thiscellular transcription factor, it was reasonable to hypothesizethat BZLF1 may block upregulation of MHC class I expressionby LMP1 through a mechanism involving NF- ${kappa}$ B. Following up onthe work of Dreyfus et al. (13), we demonstrated that BZLF1can directly inhibit the constitutive activation of NF- ${kappa}$ B inEBV-negative B cells by as much as 50% (Fig. 7A). Interestingly,this negative effect of BZLF1 on NF- ${kappa}$ B activation is not sufficientto explain the inhibition of LMP1-mediated upregulation of MHCclass I expression by BZLF1. Investigation of the effect ofBZLF1 on the activation of NF- ${kappa}$ B by LMP1 demonstrated that BZLF1could not substantially block LMP1-mediated NF- ${kappa}$ B activation(Fig. 7B). On the other hand, expression of I ${kappa}$ B ${alpha}$ ${Delta}$ N blocked notonly LMP1-mediated but also constitutive NF- ${kappa}$ B activation. Thus,I ${kappa}$ B ${alpha}$ ${Delta}$ N has a partial inhibitory effect on LMP1-mediated upregulationof MHC class I expression and a dramatic inhibitory effect onLMP1-mediated NF- ${kappa}$ B activation, whereas BZLF1 can totally blockLMP1-mediated MHC class I upregulation while having little inhibitoryeffect on LMP1-mediated NF- ${kappa}$ B activation. While these observationsdo not contradict evidence implicating NF- ${kappa}$ B activation in LMP1-mediatedinduction of MHC class I expression (36), they do suggest thatBZLF1 mediates its inhibitory effects on LMP1 predominantlyvia another pathway.

This study has identified a novel role for BZLF1 in completelyinhibiting the ability of LMP1 to upregulate expression of cellsurface MHC class I molecules. Since LMP1 is also known to induceexpression of MHC class II molecules, CD40, and CD54 in B cells(51, 59, 62), this function of BZLF1 may be sufficient to accountfor the reduced expression of all these cellular proteins followingthe switch from latency III to the lytic cycle (Fig. 3). Themore severe reduction in MHC class I expression relative tothe other LMP1-regulated genes may be a consequence of interferencewith the ability of LMP1 to alter proteasome composition andto upregulate expression of TAP-1 and TAP-2 (51). Alternatively,as has been observed with other herpesviruses, it is possiblethat additional lytic-cycle genes specifically interfere withthe antigen presentation pathway to augment the inhibitory effectof BZLF1 on LMP1 function.

ACKNOWLEDGMENTS

We gratefully acknowledge the financial support of the MedicalResearch Council and the Wellcome Trust, which funded this work.

We thank Paul Brennan, Gavin Wilkinson, Anja Mehl, Ceri Fielding,and Eddie Wang for practical assistance and for critical reviewof the manuscript.

FOOTNOTES

* Corresponding author. Mailing address: Section of Infection and Immunity, University of Wales College of Medicine, Tenovus Building, Cardiff CF14 4XX, United Kingdom. Phone: 44 (0) 29 20 742579. Fax: 44 (0) 29 20 743868. E-mail: RoweM{at}cf.ac.uk.

REFERENCES

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