Latent Membrane Protein 1 of Epstein-Barr Virus Induces CD83 by the NF-{kappa}B Signaling Pathway

Epstein-Barr virus (EBV) infects human resting B cells and transformsthem in vitro into continuously growing lymphoblastoid celllines (LCLs). EBV nuclear antigen 2 (EBNA2) is one of the firstviral proteins expressed after infection. It is able to transactivateviral as well as cellular target genes by interaction with cellulartranscription factors. EBNA2 target genes can be studied easilyby using an LCL (ER/EB2-5) in which wild-type EBNA2 is replacedby an estrogen-inducible EBNA2. Since the cell surface moleculeCD83, a member of the immunoglobulin superfamily and a markerfor mature dendritic cells, appeared on the surface of ER/EB2-5cells within 3 h after the addition of estrogen, we analyzedthe regulation of CD83 induction by EBV in more detail. Despiteits rapid induction, CD83 turned out to be an indirect targetgene of EBNA2. We could show that the viral latent membraneprotein 1 (LMP1) is responsible for the induction of CD83 byusing an LCL expressing a ligand- or antibody-inducible recombinantnerve growth factor receptor-LMP1 fusion protein. The inducibilityof the CD83 promoter by LMP1 was mediated by the activationof NF- ${kappa}$ B, as seen by use of luciferase reporter assays usingthe CD83 promoter and LMP1 mutants. Additionally, fusion constructsof the transmembrane domain of LMP1 and the intracellular signalingdomain of CD40, TNF-R1, and TNF-R2 likewise transactivated theCD83 promoter via NF- ${kappa}$ B. Our studies show that CD83 is also atarget of the NF- ${kappa}$ B signaling pathway in B cells.

INTRODUCTION

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Introduction

Epstein-Barr virus (EBV) is a B-lymphotropic gammaherpesvirusthat is associated with several human malignant diseases, includinglymphoproliferations in immunocompromised individuals, Burkitt'slymphoma, nasopharyngeal carcinoma, and Hodgkin's disease. Invitro, EBV transforms resting human B lymphocytes into continuouslyproliferating lymphoblastoid cell lines (LCLs). In these cells,EBV expresses six nuclear proteins (EBNA1, -2, -3A, -3B, -3C,and -LP), three integral latent membrane proteins (LMP1, LMP2A,and LMP2B), two small nuclear RNAs (EBV-encoded RNAs EBER1 andEBER2), and BamHI-A rightward transcripts. EBNA1, -2, -3A, and-3C as well as LMP1 seem to be absolutely required for B-cellimmortalization by EBV (for review, see references 6 and 30).

Together with EBNA-LP, EBNA2 is the first viral protein expressedin infected cells and is absolutely required for initiationand maintenance of immortalization (29). EBNA2 is a master regulatorthat transactivates viral (e.g., LMP1 and LMP2) and cellular(e.g., CD21, CD23, and c-myc) genes involved in B-cell activationand induction of proliferation (27, 29). Additional B-cell activationmarkers and adhesion molecules such as CD39, CD40, CD54, andCD58 are induced by EBNA2 target genes (6, 30). EBNA2 by itselfdoes not bind to DNA directly. It activates its target genesby interacting with cellular proteins, such as RBP-J ${kappa}$ , PU.1,and AUF1, directly or indirectly (13, 17, 21, 37, 54, 62).

To dissect the early steps in B-cell immortalization, we establishedan LCL in which the function of EBNA2 has been rendered inducible.EBNA2 was fused to the hormone binding domain of the estrogenreceptor (ER), and the fusion gene was used to rescue immortalizationby the transformation-incompetent P3HR1 virus, generating aconditional LCL (ER/EB2-5 [29]). In the presence of estrogenthe ER-EBNA2 fusion protein is located in the nucleus and cantransactivate its target genes, whereas in the absence of estrogenthe ER-EBNA2 fusion protein is sequestered to the cytoplasm.ER/EB2-5 cells proliferate in the presence of estrogen, andtheir growth is arrested when estrogen is withdrawn.

LMP1 is a direct target gene of EBNA2. It is an integral membraneprotein of 386 amino acids (aa) composed of a short intracellularN terminus, six hydrophobic transmembrane domains, and an intracellularC terminus including three functional domains, CTAR1, CTAR2,and CTAR3 (for C-terminal activator region). LMP1 is the onlyEBV protein able to transform rodent fibroblasts (4, 42, 58).It binds tumor necrosis factor receptor (TNFR)-associated factors(TRAF1, -2, -3, and -5) directly via the PxQxT site in CTAR1(7, 9, 10, 43, 50). TNFR-associated death domain protein (TRADD)interacts with tyrosines 384 and 385 in the CTAR2 domain, therebyrecruiting TRAF2 to the complex (25). In addition, TRAF6 isrecruited to the complex by indirect interaction with CTAR1and CTAR2 (52). By virtue of its transmembrane domain, LMP1acts as a constitutively active receptor of the TNFR family(12, 16, 43). Members of the TNFR family play an important rolein the functional regulation of lymphocytes, including theiractivation, differentiation, proliferation, and survival. LMP1thus shares some functional homology with CD40 (16, 20, 33,57).

LMP1 activates its target genes via different signaling pathwaysthat include NF- ${kappa}$ B, AP-1, p38-MAPK/ATF, and STAT (11, 15, 18,32, 36). Both CTAR1 and CTAR2 contribute to NF- ${kappa}$ B activation,although to a different extent (23, 41). Upon recruitment ofTRAF2 and TRAF6 to LMP1, the inhibitor of ${kappa}$ B kinase complex becomesactivated and phosphorylates I- ${kappa}$ B ${alpha}$ at Ser-32 and Ser-36. I- ${kappa}$ B ${alpha}$ isubiquitinated and targeted for proteasomal degradation (19,22). NF- ${kappa}$ B is additionally phosphorylated and translocated intothe nucleus to activate its target genes (28).

CD83 is a cell surface glycoprotein with a molecular weightof 40 to 45 kDa that belongs to the immunoglobulin (Ig) superfamily.It consists of an N-terminal extracellular V-type Ig-like domain,a transmembrane domain, and a short 39-aa cytoplasmic tail (38,61). CD83 has been described as a marker of mature dendriticcells (DCs), including Langerhans' cells and interdigitatingreticulum cells in the T-cell zones of the lymph nodes, andof activated B and T lymphocytes (60). In immature monocyte-derived(Mo) DCs CD83 is upregulated after stimulation with lipopolysaccharide,tumor necrosis factor alpha (TNF- ${alpha}$ ), or CD40 ligand (2, 3, 8,39). Furthermore, CD83 is expressed on Hodgkin cells (55). Granulocyte-macrophagecolony-stimulating factor and TNF- ${alpha}$ CD83 expression is inducedon monocytes, granulocyte-precursor cells, and myelocytes bythe addition of a high dose of interleukin-4 (44, 60). CD83has also been reported to be expressed on polymorphonuclearneutrophils (24, 59).

Recently, a role for CD83 in CD4⁺-T-cell development was demonstratedby researchers studying CD83^-/- mice (14). CD83 plays a regulatoryrole during T-cell differentiation and affects the decisionthat governs the development of singly positive (SP) CD4⁺ Tcells in the thymus. Reduction of SP CD4⁺ T cells in CD83^-/-mice in the thymus also resulted in a reduction of naïveCD4⁺ T cells in the periphery. CD83 was also shown to be expressedon thymus epithelial cells (TEC) (14).

By studying the induction of cellular genes upon addition ofestrogen to estrogen-deprived ER/EB2-5 cells, we have observedthat CD83 is induced by viral proteins. The rapid inductionof CD83 within 2 hours after the addition of estrogen promptedus to investigate the mechanism of CD83 induction. By usinga derivative ER/EB2-5 cell line expressing LMP1 constitutivelyand an LCL expressing a conditional LMP1 gene, we were ableto demonstrate that CD83 is a target of LMP1. The analysis ofLMP1 mutants and CD83 promoter deletion constructs revealedthat NF- ${kappa}$ B is the critical transcription factor responsible forLMP1-mediated upregulation of CD83 expression.

MATERIALS AND METHODS

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Materials and Methods

Cell lines and culture conditions. ER/EB2-5 cells were cultured in RPMI 1640 medium supplementedwith 10% fetal calf serum (Dynamics, Heidelberg, Germany), 100U of penicillin per ml, 100 µg of streptomycin per ml,1 mM sodium pyruvate, 1% L-glutamine (all from Invitrogen/LifeTechnologies), and 2 µM ß-estradiol (Sigma Aldrich).For depletion of estrogen, cells were washed three times inphosphate-buffered saline supplemented with 10% fetal calf serumand were resuspended in supplemented RPMI 1640 medium withoutß-estradiol. 293-T cells were cultured in Dulbecco'smodified Eagle medium with the same supplements as those usedfor ER/EB2-5 cells.

The LCL B2264-19/3 was generated by infection of primary humanB lymphocytes (isolated from cord blood) with recombinant EBVin which LMP1 had been replaced by a nerve growth factor receptor(NGF-R)-LMP1 fusion gene consisting of aa 1 to 279 of the humanlow-affinity NGF-R fused to aa 192 to 386 of LMP1. The cellswere grown in supplemented RPMI 1640 medium on ${gamma}$ -irradiated WI38human fibroblasts (obtained from American Type Culture Collection)as a feeder layer. For induction of the NGF-R-LMP1 fusion protein,B2264-19/3 cells were removed from the WI38 feeder layer for1 week and then 5 x 10⁵ cells/ml were treated with 0.5 µgof anti-NGF-R antibody (hybridoma supernatant no. HB8737; AmericanType Culture Collection) per ml. For cross-linking, 5 µgof goat anti-mouse secondary antibody (IgG plus IgM [heavy-plus-lightchains]; Dianova) per ml was added 1 h later for the indicatedtimes.

FACS analysis. For fluorescence-activated cell sorter (FACS) analysis cellswere washed once and incubated with the indicated primary antibodiesor isotype controls (IgG1, IgG2a, and IgG2b). Antibodies forhuman CD10, CD16, CD21, CD23, CD38, CD39, CD40, CD54, CD58,and CD95 and IgM were purchased from Dianova; antibodies forhuman CD80, CD86, HLA-A, -B, -C, -DR, -DP, and -DQ were purchasedfrom Pharmingen/Becton Dickinson and anti-CD83 (HB15A) antibodywas purchased from Coulter Immunotech (Marseilles, France).Goat anti-mouse antibody was used as secondary antibody (Dianova).Dead cells were excluded by propidium iodide staining. Sampleswere analyzed with the FACS Calibur instrument (Becton Dickinson).

Northern blot analysis. Total RNA was prepared using the Qiagen RNeasy Midi kit accordingto the manufacturer's instructions (Qiagen, Hilden, Germany).Ten micrograms of total RNA per lane was subjected to electrophoresisand afterwards blotted onto a nylon membrane (Hybond N⁺; AmershamPharmacia) as described previously (49). Membranes were hybridizedwith a CD83 full-length cDNA probe (kindly provided by J. Hauber,Hamburg, Germany) or a PCR product of glyceraldehyde-3-phosphatedehydrogenase (GAPDH) (primers 5'-TCCACCACCCTGTTGCTGTA-3' and5'-ACCACAGTCCATGCCATCAC-3') radiolabeled with [ ${alpha}$ ³²-P]dCTP accordingto the manufacturer's protocols (Rediprime II; Amersham Pharmacia).

Cell fractionation and Western blot analysis. All subcellular fractionations were done as described previously(51). Briefly, 1 x 10⁸ to 3 x 10⁸ proliferating or estrogen-depletedER/EB2-5 cells were resuspended in homogenization buffer (10mM Tris-acetate [pH 7.0], 250 mM sucrose, 1 mM phenylmethylsulfonylfluoride, 5 µg of pepstatin A per ml, 10 µg of leupeptinper ml), subjected to Dounce homogenization, and fractionatedinto plasma membrane (PM)-nucleus (2 min at 4,000 x g), endosomal-lysosomal(2 min at 100,000 x g), and microsomal (10 min at 400,000 xg) compartments by differential centrifugation. The supernatantafter centrifugation at 400,000 x g was defined as cytosol.

For Western blot analysis, 100 µg of the protein extractswas electrophoretically separated on sodium dodecyl sulfate-10and 15% polyacrylamide gels under reducing conditions and transferredonto a polyvinylidene difluoride membrane (Hybond P; AmershamPharmacia). Membranes were blocked for 1 h in TBST buffer (10mM Tris-HCl [pH 7.5], 20 mM NaCl, 1% Tween 20) containing 5%dry milk (Merck) and then incubated in TBST containing 3% drymilk overnight at 4°C with either anti-CD83, anti-CD86,anti-HLA-A, -B, or -C, or anti-LMP1 (Becton Dickinson) antibodies.After being washed, membranes were incubated with peroxidase-labeledgoat anti-mouse secondary antibody (Dianova) in TBST containing3% dry milk for 1 h at room temperature. Finally, blots werewashed three times in TBST containing 3% dry milk. Proteinswere visualized with the enhanced chemiluminescence (ECL) system(Amersham Pharmacia Biotech, Uppsala, Sweden).

Plasmid construction and mutagenesis. The expression plasmids pSV-LMP1, pSV-LMP1 (PQT-AAA), pSV-LMP1(PQT-AAA/Y384G), pSV-LMP1 ${Delta}$ 194-386, p35, pSV-LMP1:CD40, and pSV-LMP1:TNF-R2have been described previously (16, 19, 31, 32, 53). The expressionplasmid pSV-LMP1:HA/TNF-R1 was cloned by a PCR approach froma TNF-R1 cDNA into the pSV-LMP1 plasmid. The ß-galactosidasereporter PGKßGal was kindly provided by S. Wagener.The plasmids pGL CD83 (-3037), pGL CD83 (-261), pGL CD83 (-123),and pGL CD83 (-123mut) have been described previously (5). pGLBasic was purchased from Promega.

Transient transfection and luciferase reporter assay. 293-T cells (4 x 10⁵ per well) were seeded in a six-well plateand transfected the following day with 2 µg of DNA usingLipofectamine (Life Technologies/Invitrogen) according to themanufacturer's protocol. Vector DNA was added to adjust forequal amounts of transfected DNA. After 16 to 20 h, cells wereharvested, lysed in extraction buffer (10% [wt/vol] glycerine,1% [wt/vol] Triton X-100, 2 mM EDTA [pH 8.0], 25 mM Tris-HCl[pH 7.8], 2 mM dithiothreitol), and centrifuged, and the supernatantwas collected. Ten microliters of the protein extract was measuredin a Mikro Lumat LB96P (Berthold, Wildbach, Germany) by adding50 µl of the luciferase assay buffer [20 mM Tricin, 107mM 4(MgCO₃) · Mg(OH)₂ · 5H₂O, 2.67 mM MgSO₄, 0.1mM EDTA, 33.3 mM dithiothreitol, 270 µM acetyl-coenzymeA (Roche), 530 µM ATP (Roche), and 470 µM D-Luciferin(Roche)]. For the ß-galactosidase assay, 10 µlof protein extract was incubated for 20 min in 100 µlof reaction buffer A (100 mM Na₂HPO₄-NaH₂PO₄ [pH 8.0], 0.1 mMMgCl, 1% Galacton-Plus [Applied Biosystems]) and measured ina Mikro Lumat LB96P with the addition of 50 µl of reactionbuffer B (0.2 M NaOH, 10% Emerald-Enhancer [Applied Biosystems]).The reporter activity was calculated relative to that of ß-galactosidaseexpression. All data were obtained from at least three independentexperiments, and each experiment was performed in duplicate.The relative promoter activities were depicted as means ±standard deviations (SD).

RESULTS

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Results

CD83 is strongly induced in ER/EB2-5 cells after addition of estrogen. To study the regulation of cellular genes by EBNA2, we usedthe LCL ER/EB2-5 in which wild-type EBNA2 is replaced by estrogen-inducibleEBNA2. ER/EB2-5 cells were deprived of estrogen for 4 days,and the expression of a panel of representative B-cell surfacemarkers was determined in these cells as well as in cells thathad been reinduced by the addition of estrogen (Fig. 1). Severalgenes, those for CD38, IgM (26), and HLA-A, -B, and -C, werefound to be upregulated upon withdrawal of estrogen. Severalsurface markers known to be induced by EBV were poorly, if atall, downregulated, indicating that the half-lives of theseproteins are probably too long to see pronounced effects inthis experimental setting (CD10, CD16, CD21, CD23, CD39, CD40,CD54, CD58, CD80, and CD95). The pattern of expression was heterogeneousfor CD86 upon withdrawal of estrogen. Only CD83 and HLA-DR,-DP, and -DQ were uniformly downregulated. We focused our attentionon CD83, because CD83 had completely disappeared from the surfacesof estrogen-deprived ER/EB2-5 cells (Fig. 1) and was rapidlyinduced upon the addition of estrogen (see Fig. 3B). To determinewhether CD83 was degraded or just removed from the cell surface,estrogen-deprived and -induced cells were fractionated and thefractions representing the various subcellular compartmentswere subjected to gel electrophoresis and Western blotting.As shown in Fig. 2, CD83 was present mainly in the endosomal-lysosomalfraction of estrogen-treated ER/EB2-5 cells and was almost undetectablein any of the fractions after estrogen deprivation. In contrast,the representation of CD86 in the various cellular compartmentsremained virtually unaltered despite the fact that CD86 wasdownregulated to a considerable extent when estrogen was withdrawn.Notably, CD83 visualized by Western blotting appeared as manydistinct bands in the gel, presumably reflecting the large andvariable degree of glycosylation. This indicated that the regulatedexpression of CD83 on the cell surface is not a consequenceof cellular redistribution; rather, it represents rapid degradationand resynthesis of CD83 upon withdrawal and then addition ofestrogen, respectively.

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FIG. 1. CD83 disappears from the surface of ER/EB2-5 cells upon estrogen deprivation. Expression of cell surface markers on ER/EB2-5 cells proliferating continuously in the presence of estrogen (shaded) or deprived of estrogen for 96 h (thick lines) as measured by flow cytometry. Isotype controls are presented as dotted lines.

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FIG. 3. CD83 mRNA disappears rapidly after estrogen withdrawal (A) and accumulates upon addition of estrogen to hormone-deprived ER/EB2-5 cells (B). Proliferating ER/EB2-5 cells (+) were depleted of estrogen for 24 to 96 h (A) and then estrogen was added to hormone-deprived cells for 0 to 48 h as indicated (B). Cells were harvested at the given time points for FACS analysis and RNA preparation. Northern blots with 10 µg of RNA were hybridized with ³²P-labeled CD83 (upper panel) and GAPDH (middle panel) probes. Equal loading of the gel is documented by ethidium bromide staining (lower panel) of the 18S and 28S ribosomal RNAs. To better visualize the decrease of CD83 RNA over time, the Northern blot shown in panel A was exposed about 10 times longer than the one in panel B. The shaded histograms represent FACS analysis for CD83 expression of cells after estrogen depletion (A) or estrogen addition (B).

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FIG. 2. CD83 is degraded and not internalized upon withdrawal of estrogen. A Western blot for detection of LAMP-1, HLA-A, -B, and -C, CD83, and CD86 in various subcellular compartments (PM-nucleus, endosomes-lysosomes, microsomes, and cytosol, as indicated at the top) of estrogen-treated ER/EB2-5 cells (+ estrogen) and estrogen-depleted cells (depleted for 4 days) (- estrogen) is shown. Estrogen-treated and estrogen-deprived cells were fractionated into different subcellular compartments as described in Materials and Methods, and the respective proteins were detected by Western blotting. LAMP-1 was included as a marker for the endosomal-lysosomal compartment.

To look at CD83 expression at the transcriptional level, Northernblots were performed with total RNA isolated from estrogen-deprivedand estrogen-treated ER/EB2-5 cells at different times afterwithdrawal and addition of estrogen, respectively. As shownin Fig. 3A, CD83 RNA declined rapidly and continuously within24 to 48 h after estrogen deprivation and reappeared as earlyas 2 h after the addition of estrogen (Fig. 3B). CD83 RNA expressionstrongly increased up to 6 h and then gradually declined untila low steady-state level was reached at about 18 h upon additionof estrogen. The overshooting expression of CD83 RNA to a veryhigh level between 2 and 12 h after the addition of estrogendoes not seem to be represented to the same extent at the levelof the CD83 protein (Fig. 3B, histogram). In summary, CD83 israpidly induced after induction of EBNA2 in ER/EB2-5 cells andcompletely degraded after repression of EBNA2 by estrogen withdrawal.

CD83 is a LMP1 target gene. To analyze whether CD83 is directly or indirectly transactivatedby EBNA2, estrogen-depleted ER/EB2-5 cells were treated withestrogen in the presence and absence of cycloheximide (CHX)and with CHX alone. RNA was isolated after 3, 6, and 12 h. Inductionof CD83 was only marginally affected by treatment with CHX plusestrogen compared to with CHX alone (data not shown). This indicatedthat CD83 is not a direct EBNA2 target gene and raised the questionof which of the EBNA2 target genes is responsible for inductionof CD83. c-myc could be ruled out as a mediator of CD83 expressionsince CD83 is absent from A1 (data not shown) and P493-6 (45)cells. A1 and P493-6 are ER/EB2-5 derivative cell lines thatexpress c-myc constitutively from the Ig ${kappa}$ regulatory elementsor under the control of tetracycline and are able to proliferatein the absence of estrogen (46, 47).

A second direct target gene of EBNA2 is viral LMP1. To demonstratethe effect of LMP1 on CD83 expression, we made use of a conditionalLMP1 system developed by U. Dirmeier et al. (submitted). Inthis system primary B cells have been immortalized by recombinantB95-8 virus in which the viral LMP1 gene is replaced by an NGFreceptor-LMP1 fusion gene consisting of the transmembrane andextracellular domains of the NGF receptor and the intracellularsignaling portion of LMP1 (16). Signaling through LMP1 was renderedinducible by the ligand (NGF) or by the addition of a monoclonalantibody directed against the receptor (Fig. 4A) (16, 52). Inthis cell line CD83 expression is induced as early as 30 minafter cross-linking. It reaches a maximum after 3 h and declinesto low levels similarly to estrogen-deprived ER/EB2-5 cellsthat have been restimulated by the addition of estrogen (Fig.4B and C). These data show that CD83 expression is activatedby LMP1 signaling.

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FIG. 4. CD83 is induced by LMP1. (A) Experimental system. LMP1 was activated by antibody-mediated NGF-R cross-linking in a cell line immortalized by recombinant EBV and expressing a fusion protein consisting of the extracellular and transmembrane domains (light gray) of the NGF-R and the intracellular signaling domain of LMP1, including CTAR1, -2, and -3 (dark gray cylinder) at the C terminus. (B) RNA was prepared at different time points after receptor cross-linking and was analyzed for CD83 expression by Northern blot analysis (upper panel). The lower panel shows the ethidium bromide-stained gel with rRNAs indicated at the right to show equal loading. (C) At the same time points, CD83 cell surface expression was monitored by FACS analysis. The shaded histograms represent the measurements of CD83 protein on the cell surface after the addition of estrogen.

The CD83 promoter is induced by LMP1 through activation of NF- ${kappa}$ B. To study the mechanism of CD83 induction, we cloned the CD83promoter in front of the luciferase reporter gene and studiedits induction by LMP1 by transient transfection experimentsin 293-T cells. Four SP1 binding sites and one NF- ${kappa}$ B bindingsite are located in the TATA-less CD83 promoter within 260 bpupstream of the translation start site (5, 34, 40). Four differentconstructs were used (Fig. 5) as follows. The first representsthe CD83 wild-type promoter and consists of 3,037 bp upstreamof the translation start site (-3,037). The second consistsof 261 bp upstream of the translation start site, includingthe four SP1 sites and the NF- ${kappa}$ B binding sequence (-261). Thethird construct carries the NF- ${kappa}$ B site without the four SP1 sites(-123). The last one has a mutated NF- ${kappa}$ B site (-123mut).

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FIG. 5. CD83 promoter constructs. The genomic sequence of the human CD83 promoter was cloned into the vector pGL Basic containing the luciferase gene without promoter sequences. The pGL CD83 (-3,037) plasmid contains 3,037 bp upstream of the translation initiation site. The start codon of luciferase is indicated by a bent arrow. The CD83 promoter contains an NF- ${kappa}$ B site (dark gray box) and four SP1 binding sequences (black boxes). pGL CD83 (-261) contains the CD83 promoter sequence up to position -261, including the four SP1 and NF- ${kappa}$ B sites. pGL CD83 (-123) contains only the NF- ${kappa}$ B site. In pGL CD83 (-123mut), the NF- ${kappa}$ B site is mutated at position -115 to -106 (light gray box) so that NF- ${kappa}$ B cannot bind (5). All CD83 promoter mutants were generated by PCR and verified by sequencing.

As shown in Fig. 6A, cotransfection of the CD83 promoter-luciferasereporter constructs with LMP1 resulted in a 14- and 10-foldinduction of the 3,037- and 261-bp constructs. LMP1 itself hada twofold effect on the promoterless pGL luciferase vector containinga small unspecific induction luciferase by LMP1. Deletion ofthe SP1 sites had no effect on the long 3,037-bp construct (datanot shown) and reduced transactivation by LMP1 in the 123-bpconstruct only slightly. Mutation of the NF- ${kappa}$ B site abolishedtransactivation by LMP1 completely (Fig. 6A), suggesting thatNF- ${kappa}$ B is an important factor mediating the effect of LMP1 onthe CD83 promoter. This was confirmed by an independent lineof evidence. LMP1 mutants were cotransfected with the CD83 promoter-luciferasereporter constructs in which either the whole C terminus, theCTAR1 domain (PQT to AAA), the CTAR2 domain (Tyr384 to Gly384),or both CTAR domains were mutated. The data were virtually identicalfor the 261-bp (Fig. 6B) and 3,037-bp constructs (data not shown).Mutation of each CTAR domain individually decreased the levelof transactivation of the CD83 promoter by LMP1 to a differentextent (about fourfold for CTAR2 and about twofold for CTAR1),whereas mutation of both sites abolished transactivation byLMP1 completely, similar to the deletion of the complete C terminus.These data show that LMP1 induces CD83 expression through activationof NF- ${kappa}$ B.

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FIG. 6. The CD83 promoter is activated by LMP1 expression plasmids in transient transfections. (A) Fifty nanograms of CD83 promoter-reporter constructs were transfected into 293-T cells together with 0.5 µg of LMP1 and 10 ng of ß-galactosidase expression plasmids (black bars). (B) The LMP1 expression plasmid (pSV-LMP1) or LMP1 mutant expression plasmid pSV-LMP1 ( ${Delta}$ 194-386), pSV-LMP1 (PQT $->$ AAA), pSV-LMP1 (Y384G), or pSV-LMP1 (PQT $->$ AAA/Y384G) (0.5 µg) and 10 ng of ß-galactosidase reporter plasmid were cotransfected with 50 ng of the CD83 promoter-reporter construct (-261) or pGL Basic, as indicated by black and white bars, respectively. Transfections were harvested the following day, and the luciferase values were normalized, with ß-galactosidase as a standard. The CD83 promoter activity is given as fold induction versus mock-transfected controls. Error bars show standard deviations for at least three independent experiments.

The CD83 promoter is also activated by chimeric LMP1-CD40, LMP1-TNFR1, and LMP1-TNFR2. LMP1 acts like a constitutively active member of the TNFR familyand shares with other members of the family a number of signalingmolecules that are involved in signal transmission from thecell surface to the nucleus, including TRAF2, TRAF6, and TRADD.In vivo, these receptors have overlapping yet distinct functionsin the regulation of the immune response and apoptosis. CD83expression can be induced on dendritic cells by CD40 ligand(8) or by TNF- ${alpha}$ (5, 39, 48). Therefore, we made constitutivesignaling fusion proteins of the intracellular signaling domainsof CD40, TNFR1, and TNFR2 with the transmembrane domain of LMP1(16) to test whether these receptor domains could also contributeto CD83 promoter activation. All three fusion constructs (LMP1-CD40,LMP1-TNFR1, and LMP1-TNFR2) transactivated the CD83 promoter-luciferasereporter constructs to the same extent as LMP1 (Fig. 7), indicatingthat activation of NF- ${kappa}$ B is the critical step for CD83 inductionthrough different receptors.

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FIG. 7. The CD83 promoter is also activated by TNFR family members via NF- ${kappa}$ B. CD83 promoter-reporter constructs (50 ng) as described for Fig. 5 were cotransfected into 293-T cells with 0.5 µg of LMP1-CD40 (A), LMP1-TNFR1, or LMP1-TNFR2 expression plasmids (B). In the case of LMP1-TNFR1, 1.5 µg of p35 plasmid was cotransfected to avoid apoptosis. The CD83 promoter activity is shown as fold induction compared to mock-transfected cells (black bars). Error bars indicate the standard deviations for three independent experiments.

DISCUSSION

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Discussion

To study the phenotypic changes induced by gene products ofEBV in B cells, we have made use of a conditional EBV-immortalizedB-cell line in which the function of the viral gene productEBNA2 is controllable by estrogen. As expected, many of theactivation markers and adhesion and costimulatory moleculeswere upregulated by EBV. Only a few of the surface markers studied(i.e., CD38, IgM, and HLA-A, -B, and -C) were found to be regulatedin an opposite fashion, i.e., they were downregulated by viralgene products and upregulated when estrogen was withdrawn. Amongthe surface markers studied, CD83 attracted our particular attentionbecause it was the only surface molecule that totally disappearedfrom the cell surface after estrogen withdrawal and rapidlyreappeared after the addition of estrogen. The rapid time courseof disappearance and reappearance of CD83 on the cell surfaceprompted us to study the mechanism of regulation of CD83 expressionby viral gene products in more detail. The rapid removal ofCD83 from the cell surface is not due to redistribution of CD83inside the cell. In fact, CD83 has a half-life that is significantlyshorter than those of most other surface molecules and is rapidlydegraded and resynthesized upon removal and addition of estrogen,respectively. This regulation at the protein level is also reflectedat the RNA level. CD83 RNA declined within 24 h after removalof estrogen and was virtually gone after 48 h. CD83 RNA wasdetected as soon as 2 h after the addition of estrogen, peakedat 6 h, and leveled off to reach a constant level of expressionafter about 18 h.

The rapid induction of CD83 after the addition of estrogen raisedthe question of whether CD83 might be a direct target gene ofEBNA2. This turned out not to be the case. The CD83 RNA leveldid not increase to a significantly higher level in the presenceof estrogen plus CHX compared to the level with CHX alone (datanot shown). Twofold evidence indicated that CD83 is a targetgene of LMP1. Firstly, CD83 remained expressed upon withdrawalof estrogen in a cell line in which LMP1 was constitutivelyexpressed (data not shown), and secondly, in a cell line witha conditional LMP1 gene CD83 was induced when the NGF-R-LMP1fusion protein was cross-linked on the cell surface (Fig. 4).

To identify the mechanism by which CD83 is induced by LMP1,we performed CD83 promoter studies. A 3-kb fragment encompassingthe CD83 promoter as well as 261- and 123-bp derivatives thereofconferred inducibility by LMP1. Four potential SP1 sites locatedat a distance between -180 and -261 had no effect on the inducibilityof the promoter by LMP1, whereas deletion or mutation of theNF- ${kappa}$ B site completely abolished inducibility by LMP1. This isin agreement with the observation that NF- ${kappa}$ B regulates CD83 expressionin activated T lymphocytes, monocytic U937 cells, and dendriticDC2.4 cells (5, 40). McKinsey et al. (40) identified two NF- ${kappa}$ Bbinding sites in the CD83 promoter at positions -115 to -106and -91 to -82 (relative to the translation initiation start),but the NF- ${kappa}$ B site at position -115 to -106 seems to be sufficientfor the LMP1-mediated induction of the CD83 gene (Fig. 6 and7). Another approach verified that NF- ${kappa}$ B is indeed the criticalplayer for mediating the effect of LMP1 on the CD83 promoter.Mutation of the CTAR1 or CTAR2 domain of LMP1 decreased inducibilityby LMP1 by a factor of 2 and 4, respectively, whereas a doublemutation affecting CTAR1 as well as CTAR2 completely abolishedinducibility by LMP1 in a fashion similar to the deletion ofthe complete C terminus of LMP1.

Since LMP1 is a member of the TNFR family and stimulation ofother family members through CD40 ligand or TNF- ${alpha}$ also contributesto CD83 induction on dendritic cells, we asked whether thesereceptors use the same route to induce CD83 expression. Thisis in fact the case. Chimeric receptors consisting of the transmembranedomain of LMP1 and the signaling domains of CD40, TNFR1, andTNFR2 also induced the CD83 promoter through NF- ${kappa}$ B activation.

The fact that the CD83 promoter is induced by LMP1 through NF- ${kappa}$ Bmay partly explain the kinetics of CD83 RNA induction by LMP1.Induction of CD83 RNA is strongly overshooting, peaks at a veryhigh level 6 h after the addition of estrogen, and reaches afairly low steady-state expression level in continuously proliferatingEBV-immortalized cells. This pattern of expression may be explainedby the fact that NF- ${kappa}$ B, by inducing its own inhibitor, I- ${kappa}$ B, inducesa negative feedback loop that limits the expression of its targetgenes under steady-state conditions.

A novel mechanism of regulation of CD83 expression has beendescribed for dendritic cells (35) that affects the efficiencyof RNA transport from the nucleus to the cytoplasm. In our cellsystem there is no evidence that CD83 expression might alsobe regulated at this level. The stringent regulation of CD83RNA in estrogen-deprived versus estrogen-supplemented ER/EB2-5cells rules out the idea that this mechanism contributes significantlyto regulation of CD83 expression by LMP1.

Many viruses, including herpesviruses (e.g., herpes simplexvirus and cytomegalovirus), have evolved a multitude of mechanismsthat subvert the immune system (for review, see references 1and 56). EBV is peculiar in the sense that it induces a strongimmune response against virus-infected B cells and that it enhancesrather than impairs antigen presentation. Assuming a role forCD83 in antigen presentation and T-cell stimulation, we proposethat induction of CD83 is part of this virus-induced immuneenhancement program. There are two possibilities to explainwhy EBV induces such a strong immune response against virus-infectedB cells. Firstly, a virus that is as strongly transforming asEBV might eradicate its host and eliminate its own niche forsurvival unless it elicits a strong immune response that countersthe transforming ability of the virus in vivo. Alternatively,induction of a strong immune response against virus-infectedcells may be a prerequisite for the establishment of latencyin the B-cell system in vivo. A better understanding of themechanisms by which virus latency is established in vivo mighthelp to discriminate between these possibilities.

ACKNOWLEDGMENTS

This work was supported by grants to W.H. and G.W.B. from DeutscheForschungsgemeinschaft (SFB455) and Fonds der Chemischen Industrie.

We are grateful to Josef Mautner and Franz Kohlhuber for helpfuldiscussions and reagents.

FOOTNOTES

* Corresponding author. Mailing address: Institute of Clinical Molecular Biology and Tumor Genetics, GSF-National Research Center for Environment and Health, Marchioninistrasse 25, D-81377 Munich, Germany. Phone: 49-89-7099521. Fax: 49-89-7099500. E-mail: dudziak{at}gsf.de.

Present address: Universität Tübingen, PhysiologischesInstitut, D-72076 Tübingen, Germany.

REFERENCES

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