Nuclear Factor {kappa}B-Dependent Activation of the Antiapoptotic bfl-1 Gene by the Epstein-Barr Virus Latent Membrane Protein 1 and Activated CD40 Receptor

Suppression of the cellular apoptotic program by the oncogenicherpesvirus Epstein-Barr virus (EBV) is central to both theestablishment of latent infection and the development of EBV-associatedmalignancies. We have previously shown that expression of theEBV latent membrane protein 1 (LMP1) in Burkitt's lymphoma celllines leads to increased mRNA levels from the cellular antiapoptoticbfl-1 gene (also known as A1). Furthermore, ectopic expressionof Bfl-1 in an EBV-positive cell line exhibiting a latency type1 infection protects against apoptosis induced by growth factordeprivation (B. N. D'Souza, M. Rowe, and D. Walls, J. Virol.74:6652-6658, 2000). We now report that LMP1 drives bfl-1 promoteractivity through interactions with components of the tumor necrosisfactor receptor (TNFR)/CD40 signaling pathway. We present evidencethat this process is NF- ${kappa}$ B dependent, involves the recruitmentof TNFR-associated factor 2, and is mediated to a greater extentby the carboxyl-terminal activating region 2 (CTAR2) relativeto the CTAR1 domain of LMP1. Activation of CD40 receptor alsoled to increased bfl-1 mRNA levels and an NF- ${kappa}$ B-dependent increasein bfl-1 promoter activity in Burkitt's lymphoma-derived celllines. We have delineated a 95-bp region of the promoter thatfunctions as an LMP1-dependent transcriptional enhancer in thiscellular context. This sequence contains a novel NF- ${kappa}$ B-like bindingmotif that is essential for transactivation of bfl-1 by LMP1,CD40, and the NF- ${kappa}$ B subunit protein p65. These findings highlightthe role of LMP1 as a mediator of EBV-host cell interactionsand may indicate an important route by which it exerts its cellulargrowth transforming properties.

INTRODUCTION

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Introduction

The Epstein-Barr virus (EBV) is a ubiquitous human herpesvirusthat is associated with infectious mononucleosis and a spectrumof malignant diseases including African endemic Burkitt's lymphoma(BL), anaplastic nasopharyngeal carcinoma, Hodgkin's disease,and lymphoproliferative disorders in immunodeficient individuals(for reviews, see references 59 and 102). In vitro, EBV is exceptionallyefficient at transforming and immortalizing resting human Blymphocytes leading to the outgrowth of transformed and immortalizedlymphoblastoid cell lines (LCLs) displaying elevated levelsof several cellular activation antigens and adhesion molecules(for a review, see reference 74). In an LCL, viral gene expressionis generally restricted to a limited number of latent genesthat encode six Epstein-Barr nuclear antigens (EBNA1, 2, 3A,3B, 3C, and LP), three integral membrane proteins (LMP1, LMP2A,and 2B), and two small nuclear RNAs (for a review, see reference37). Five of these (EBNA1, EBNA2, EBNA3A, EBNA3C, and LMP1)have been shown to be essential for the process of B-cell immortalization(for a review, see reference 62).

The frequent detection of LMP1 expression in many EBV-associatedmalignancies has led to the suggestion that this protein contributesto tumorigenesis. Several studies have shown that LMP1 possessesoncogenic properties. The expression of LMP1 leads to the transformationof rodent fibroblast cell lines and renders them tumorigenicin nude mice (118). In BL-derived cell lines, LMP1 induces manyof the phenotypic changes observed in EBV infection includingthe upregulation of B-cell activation markers and cell adhesionmolecules and an increased resistance to stimuli that induceapoptosis (74). In epithelial cells, LMP1 expression blocksthe normal process of differentiation, reminiscent of the undifferentiatedphenotype frequently observed in nasopharyngeal carcinoma (23).In keeping with these in vitro findings, targeted expressionof LMP1 in the skin or B-cell compartment of transgenic miceleads to the induction of epithelial hyperproliferation andlymphomagenesis, respectively (77, 120). It has also recentlybeen shown that LMP1 is critical for rendering LCLs tumorigenicin SCID mice (27).

The suppression of apoptotic death is a function of LMP1 thatcontributes to its oncogenicity. One well-documented mechanismby which LMP1 can protect against apoptosis is by upregulatingthe expression of several antiapoptotic proteins including Bcl-2,A20, and Mcl-1 (41, 53, 78, 91, 106, 119), thus raising theapoptotic threshold of the infected cell and also providingprotection against a range of apoptosis-inducing stimuli. Itwas previously shown that elevated mRNA levels from an additionalbcl-2 family member, bfl-1, are a feature of EBV-infected Blymphocytes exhibiting type 3 latency and that the expressionof LMP1 in an EBV-negative BL cell line coincided with a dramaticincrease in bfl-1 mRNA levels (30). In that study, Bfl-1 protectedagainst serum depletion-induced apoptosis when expressed inthe same cell context. Bfl-1 is an antiapoptotic protein whosepreferential expression in hematopoietic and endothelial cellsis controlled by inflammatory stimuli such as tumor necrosisfactor (TNF) and interleukin-1 (IL-1) (17, 67, 68). bfl-1 isa mouse A1 homologue and encodes a 175-amino-acid protein thatshares the highly conserved Bcl homology 1 (BH1), BH2, and BH3domains with other Bcl-2 family members. Bfl-1 has been shownto suppress p53-mediated apoptosis and to possess cell proliferationand transforming activities in vitro (28, 29, 84). Elevatedbfl-1 expression was reported in normal leukocytes and severalcancer cell lines (73, 97).

LMP1, a member of the TNF receptor (TNFR)/CD40 superfamily (5)functions as a constitutively active receptor (46) and signalsprincipally from intracellular compartments (80). Both oligomerizationand localization within glycosphingolipid-rich membrane raftsare essential for the initiation of signaling (21, 36, 56).The cytoplasmic carboxyl-terminal tail of LMP1 contains twomajor effector domains, C-terminal activating region 1 (CTAR1),also known as transformation effector site 1 (TES1), and CTAR/TES2.CTAR1 is located proximal to the membrane, binds TNFR-associatedfactors (TRAFs) (26, 61), and is essential for EBV-mediatedB-cell immortalization (65, 69, 70). CTAR2/TES2, which is locatednear the C terminus, supports the long-term growth of immortalizedB cells (64) and recruits the TNFR-associated death domain (TRADD)protein and receptor-interacting protein (34, 61, 63). Consequently,LMP1 triggers several signaling pathways that lead to the activationof transcription factors, including NF- ${kappa}$ B, STATs, AP-1, and ATF2(8, 33, 35, 45, 61, 75, 101). NF- ${kappa}$ B plays a key role in mostLMP1-stimulated gene expression (25, 52, 88, 95, 121). BothLMP1 and activated CD40 receptor initiate overlapping signalingpathways that regulate major cell fate decisions including proliferation,differentiation, and apoptosis (1, 5, 46, 51, 72, 76, 114, 122).Despite many similarities, however, they also differ substantively(for a review, see reference 79). In this regard, it has beendemonstrated that although LMP1 and CD40 can independently bindseveral of the same TRAF molecules (namely TRAF2, 3, and 5),TRAF6 binds to CD40 but not to LMP1, and TRAF1 and TRADD havebeen reported to bind to LMP1 but not to bind CD40 directly(10).

We now report for the first time that LMP1 stimulates bfl-1promoter activity in EBV-negative BL-derived cell lines andthat this process involves interactions with components of theTNFR/CD40 signaling pathway. We present evidence that this processis NF- ${kappa}$ B dependent, involves the recruitment of TRAF2, and ismediated to a greater extent by CTAR2 than by CTAR1. Activationof CD40 receptor also led to increased bfl-1 mRNA levels andan NF- ${kappa}$ B-dependent increase in bfl-1 promoter activity in thesame cell context. We delineate a 95-bp region of the promoterthat functions as an LMP1-dependent transcriptional enhancer,and we present evidence that this sequence contains a novelNF- ${kappa}$ B-like binding site that is essential for transactivationof bfl-1 by LMP1, CD40, and the NF- ${kappa}$ B subunit protein p65.

MATERIALS AND METHODS

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Materials and Methods

Cell cultures. DG75 and BL41 are EBV-negative BL cell lines (7, 104). BL41-B95-8is a derivative of BL41 that was infected with the B95-8 strainof EBV (13). MUTU-I and Rael are group I/latency 1 cell linesthat were established from EBV-positive BL biopsy specimens(48, 87). The DG75tTA-LMP1 transfectant of DG75 contains a tetracycline-regulatedLMP1 expression plasmid and has been described previously (38).All of the cell lines were maintained as suspension culturesin RPMI 1640 (Gibco) supplemented with 10% fetal bovine serum(Gibco), 2 mM glutamine, 100 µg of streptomycin/ml, and100 IU of penicillin/ml at 37°C in a humidified atmospherecontaining 5% carbon dioxide. DG75-tTA-LMP1 cells were maintainedunder selection with 800 µg of hygromycin B (Roche Diagnostics)/mland 2 mg of G418 (Roche Diagnostics)/ml as well as 1 µgof tetracycline (Sigma)/ml to repress LMP1 expression. For theinduction of LMP1, cells were washed five times in phosphate-bufferedsaline and recultured in tetracycline-free medium. The establishmentand culture of mouse fibroblastic L cell lines stably transfectedwith human CD32/Fc-gRII (CD32-L cells) or human CD40 ligand(CD40lig-L cells) have been described elsewhere (43, 98).

Plasmids. The luciferase reporter constructs -1374/+81-Luc, -1374/+81(m ${kappa}$ B-833),-1240/+81-Luc, -367/+81-Luc, and -129/+81-Luc were generatedby subcloning bfl-1 promoter sequences from a correspondingseries of chloramphenicol acetyltransferase reporter constructs(123). Thus, bfl-1 promoter sequences were amplified by PCRwith a forward oligonucleotide primer (5'-TTGCATGCCTGCAGGTCGA-3')from the multiple cloning site of the chloramphenicol acetyltransferasereporter vectors and a reverse primer (5'-gggaagcttCTAGAGCTGCCTGGTG-3')from the bfl-1 promoter, which included a HindIII restrictionsite and digestion clamp at its 5' end (shown in lowercase type).All PCR products therefore contained a common 3' terminus at+81 bp relative to the transcription start site. The PCR productswere then digested with SalI and HindIII and cloned betweenthe XhoI and HindIII sites of the promoterless luciferase reporterconstruct pGL2Basic (Promega). The SalI site was present inthe amplified portion of the polylinker at the 5' end of thebfl-1 promoter sequence. To generate -57/+81-Luc, the forwardprimer 5'-ccgctcgagGAAGGATATTATATAAAG-3' (which included anXhoI site and digestion clamp, shown in lowercase type) wasused with the same reverse primer as above to amplify the bfl-1promoter sequence between -57 bp and + 81 bp from -129/+81-Luc.The PCR product was digested with XhoI and HindIII and subclonedinto pGL2Basic as described above.

To generate pGa(-129/+1), pGa(-129/-26), pGa(-129/-34), pGa(-129/-34m ${kappa}$ B),pGa(-129/-54), and pGa(-34/-129m ${kappa}$ B), portions of the bfl-1 promoterwere amplified by PCR with forward and reverse primers thatincluded BamHI sites at their 5' ends (shown in lowercase type).The PCR primers used were as follows: -129forward, 5'-cgcggatccAAACTTTCTCTTTCATAC-3';+1reverse, 5'-cgcggatccGAGCTTGACTGAGTTATG-3'; -26reverse, 5'-cgcggatccTGATACATGGAGGCTGGT-3';-34reverse, 5'-cgcggatccGAGGCTGGTGGAATTTCTGTTTG-3'; -34reverse(NF- ${kappa}$ B mutated), 5'-cgcggatccGAGGCTGGTGAGACTTCTGTTTG-3'; -54reverse,5'-cgcggatccTTTGCATCACTTTATAAT-3'. In the case of -34reverse(NF ${kappa}$ B mutated), the base changes made to the NF- ${kappa}$ B-like site onthe sequence subcloned into pGa(-129/-34m ${kappa}$ B) are underlined inthe primer sequence. All PCR products were digested with BamHIand subcloned into the BamHI site in the polylinker of pGa50-7(81). Site-directed mutagenesis was performed with the QuikChangeXL site-directed mutagenesis kit (Stratagene). The followingpairs of complementary oligonucleotides were used to generatemutations (the introduced sequence changes are underlined):NF- ${kappa}$ B-like site at -52, 5'-GTGATGCAAACAGAAGTCTCACCAGCCTCCATGTATCATC-3'and 5'-GATGATACATGGAGGCTGGTGAGACTTCTGTTTGCATCAC-3'; AP1-likesite at -104/-94, 5'-CTTTCTCTTTCATACATATGGTATAACACAGCCTACGCACG-3'and 5'-CGTGCGTAGGCTGTGTTATACCATATGTATGAAAGAGAAAG-3'; AP1-likesite at -74/-64, 5'-GCCTACGCACGAAAGAATCTAGGAGGAAGGATATTATAAAGTG-3'and 5'-CACTTTATAATATCCTTCCTCCTAGATTCTTTCGTGCGTAGGC-3'. The 3Enh-Lucreporter construct contains three ${kappa}$ B elements upstream of a minimalconalbumin promoter linked to the firefly luciferase gene (2).The following plasmids that are used have been published elsewhere:pEFCX, pEFCX-LMP1, and pEFCX-I ${kappa}$ B ${alpha}$ DN (83); pSFFVA20 and pcDNA3-TRAF2 ${Delta}$ (6-86)(32, 34); pSG5-LMP1 (61); pSG5-LMPAAA (35); pSG5-LMPG (40);pSG5-LMPAAAG (8); pcDNAp65, pcDNAp50, and pcDNAc-Rel (123).

Transfections and reporter assays. Transfections were performed by using the DEAE-dextran method.Briefly, 10⁷ cells were washed once with phosphate-bufferedsaline and then resuspended in 1.2 ml of transfection solution(0.5 mg of DEAE-dextran [Sigma]/ml) and up to 16.0 µgof DNA in TBS (25 mM Tris-HCl [pH 7.4], 137 mM NaCl, 5 mM KCl,0.7 mM CaCl₂, 0.5 mM MgCl₂, 0.6 mM Na₂HPO₄). In any transfectionexperiment, the total amount of DNA was kept constant with anydeficiencies made up with the corresponding empty vector. Thetransfection reaction mixtures were incubated for 30 min atroom temperature. Thereafter, the cells were washed twice with10 ml of RPMI 1640-10% fetal bovine serum, resuspended in 10ml of fresh growth medium, and cultured for 24 or 48 h. In somecases, cells were stimulated for the final 12 h with anti-CD40antibodies (G28.5) before preparation of cellular extracts.Luciferase activity was determined from cell extracts by meansof a luciferase assay system (Promega Corp.) and a luminometer(Berthold Analytical Instruments) essentially according to themanufacturer's specifications. Luciferase levels were normalizedafter determining ß-galactosidase activity expressedfrom pCMVlacZ (1 µg), which was included in all transfections.ß-Galactosidase assays were performed as previouslydescribed (107) by using the same extracts that were used formeasuring luciferase activity.

Northern blot analysis. Total cellular RNA was prepared by using RNA isolator solution(Genosys) essentially according to the manufacturer's specifications.Thirty-microgram samples of total RNA were size fractionatedin 1.3% formaldehyde-agarose gels and then transferred to nitrocellulosefilters (BDH). Antisense ³²P-labeled riboprobes were synthesizedby in vitro transcription (Riboquant Multiprobe RNase protectionassay system, multiprobe hAPO-2 template set; Pharmingen) asdescribed by the manufacturer. Labeled transcripts were sizefractionated in denaturing polyacrylamide gels, and probes werelocated by autoradiography, excised, and then eluted in buffercontaining 0.5 M ammonium acetate, 10 mM magnesium acetate,1 mM EDTA (pH 8.0), and 0.1% sodium dodecyl sulfate (SDS) bythe crush and soak method (107) followed by ethanol precipitation.Probes (10⁶ cpm/ml) were hybridized to filters in 6x SSC (1xSSC is 0.15 M NaCl plus 0.015 M sodium citrate), 50% formamide,1% SDS, 0.1% Tween 20, and 100 µg of Escherichia colitRNA/ml for 16 to 24 h at 55°C. Filters were washed twicein 1x SSC-0.1% SDS at room temperature for 30 min and then twicein 0.1x SSC-0.1% SDS at 65°C for 30 min prior to exposureto X-ray film at -70°C.

Western Blot analysis. To detect LMP1, protein lysates were prepared by boiling for10 min in 2% SDS, 100 mM NaCl, 0.01 M Tris-HCl, 5% ß-mercaptoethanol,1 mM EDTA, 100 µg of phenylmethylsulfonyl fluoride/ml,and 2 µg of leupeptin/ml and briefly sonicated on ice.The lysates were then clarified by centrifugation at 13,000rpm for 10 min at room temperature. Protein from 5 x 10⁵ cellswas separated by discontinuous SDS-5 to 10% polyacrylamide gelelectrophoresis and blotted onto a nitrocellulose filter. Filterswere probed with the anti-LMP1 CS 1-4 antibody cocktail (105)diluted to 1:100 in Blotto (5% skim milk and 0.1% Tween 20 inTris-buffered saline) overnight at 4°C. Immunocomplexeswere detected with alkaline phosphatase-conjugated sheep anti-mouseimmunoglobulin G (IgG) (Promega) and visualized with 5-bromo-4-chloro-3-indolylphosphate(BCIP)-nitroblue tetrazolium liquid substrate (Sigma).

RESULTS

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Results

LMP1 transactivates the bfl-1 promoter in EBV-negative BL-derived cell lines by a mechanism that is dependent upon the transcription factor NF- ${kappa}$ B. To determine whether LMP1 could transactivate the bfl-1 promoter,a suitable promoter-reporter construct was first generated.To this end, a 1.4-kb DNA sequence from the 5' regulatory regionof the bfl-1 gene (from -1374 to + 81 relative to the transcriptioninitiation site) (123) was positioned upstream of the luciferasegene in the promoterless vector pGL2Basic (Promega) to generatethe reporter construct -1374/+81-Luc. Initially, expressionvectors derived from the plasmid pEFCX were used for the expressionof LMP1 and other effector proteins in transient transfections.Recombinant genes expressed from pEFCX are driven by the promoterfor the polypeptide chain elongation factor 1 ${alpha}$ in an NF- ${kappa}$ B-independentmanner (83). LMP1 levels expressed from pEFCX-LMP1 would nottherefore be expected to fluctuate in the presence of moleculesthat regulate activation of this transcription factor. Transienttransfections of the EBV-negative BL-derived cell lines DG75and BL41 showed that the use of increasing amounts of cotransfectedpEFCX-LMP1 led to a dose-dependent increase in luciferase activityat 24 h posttransfection when using -1374/+81-Luc as the reportervector. Similar results were obtained with both cell lines usedin this and subsequent experiments, and only the results forDG75 are presented (Fig. 1A). A maximal increase of 8.5-foldin luciferase values was detected with 2.5 µg of pEFCX-LMP1(7.8-fold in BL41). The level of expression of LMP1 in transfectedcell extracts was assessed by Western blotting, and as expected,this was seen to rise as the quantity of pEFCX-LMP1 was increasedwith no LMP1 being detected when pEFCX was used as the cotransfectedplasmid (Fig. 1A). The effect of LMP1 was mediated by the bfl-1promoter sequence, since LMP1 expression did not affect thecorresponding promoterless vector pGL2Basic (not shown). Theseresults indicate that LMP1 upregulates bfl-1 promoter activityin these EBV-negative BL-derived cell lines.

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FIG.1. LMP1 and PMA transactivate the bfl-1 promoter in DG75 cells by mechanism(s) that are dependent upon the transcription factor NF ${kappa}$ B; transactivation does not require a previously identified NF- ${kappa}$ B-binding site at position -833/-823 relative to the transcription start site. (A) Dose-dependent transactivation of the bfl-1 promoter by LMP1. DG75 cells were cotransfected with increasing amounts of either pEFCX or pEFCX-LMP1 (effector plasmids) and 2.5 µg of -1374/+81-Luc. Cells were harvested at 24 h posttransfection and analyzed for luciferase activities, which were then normalized for transfection efficiency (based on ß-galactosidase activity measured from cotransfected pCMVlacZ reporter, which was included in all transfections). Luciferase values obtained by cotransfection with pEFCX were arbitrarily assigned a value of 1.0 and activation represents the relative normalized luciferase activities obtained upon cotransfection with the effector plasmids with the quantities indicated. Selected extracts from these transfections were analyzed for LMP1 expression by Western blotting (shown underneath). (B) Inhibition of LMP1-mediated activation of the bfl-1 promoter by overexpression of a superrepressor mutant form of I ${kappa}$ B ${alpha}$ (I ${kappa}$ B ${alpha}$ DN). DG75 cells were cotransfected with 2.5 µg of pEFCX-LMP1 or empty vector pEFCX and 2.5 µg of -1374/+81-Luc together with various amounts (0, 2.5, 5.0, or 10.0 µg) of pEFCX-I ${kappa}$ B ${alpha}$ DN. Cells were harvested at 24 h posttransfection, and luciferase values were measured, normalized as above, and presented as activation (n-fold) over control (empty vector in the absence of expression of I ${kappa}$ B ${alpha}$ DN equals 1). Selected extracts from these transfections were analyzed for LMP1 expression by Western blotting (shown underneath). (C) PMA activates the bfl-1 promoter in an NF- ${kappa}$ B-dependent manner. DG75 cells were transfected with either 2.5 µg of -1374/+81-Luc or 3Enh-Luc in the presence or absence of 10.0 µg of pEFCX-I ${kappa}$ B ${alpha}$ DN and then treated with either 10^-7 M PMA or vehicle control (0.062% ethanol) at 18 h posttransfection. Cells were harvested at 24 h posttreatment, and the normalized luciferase values obtained are presented as increases (n-fold) over control values. The values obtained with transfected cells that had been treated with vehicle control were arbitrarily assigned a value of 1. (D) Neither LMP1- nor PMA-mediated activation of the bfl-1 promoter requires the known NF- ${kappa}$ B-binding site at position -833/-823 in the bfl-1 promoter. DG75 cells were cotransfected with 2.5 µg of pEFCX-LMP1 or empty vector pEFCX and 2.5 µg of -1374/+81-Luc or its NF- ${kappa}$ B-mutated derivative -1374/+81(m ${kappa}$ B-833)-Luc. In the PMA study, DG75 cells were transfected with 2.5 µg of -1374/+81-Luc or 1374/+81(m ${kappa}$ B-833) and then treated with either 10^-7 M PMA or vehicle control (0.062% ethanol) at 18 h posttransfection. Cells were harvested at 24 h either posttransfection or posttreatment (PMA or vehicle, respectively) and assayed for luciferase activity. Normalized luciferase values were expressed as activation (n-fold) over control empty vector or vehicle as appropriate.

Previous experiments in which the human bfl-1 promoter was shownto be responsive to TNF- ${alpha}$ via an NF- ${kappa}$ B-dependent pathway (123)suggested that transactivation by LMP1 might also be mediatedby this transcription factor. To directly test this hypothesis,DG75 cells were cotransfected with -1374/+81-Luc and pEFCX-LMP1together with pEFCX-I ${kappa}$ B ${alpha}$ DN, which expresses a superrepressor mutantform of I ${kappa}$ B ${alpha}$ in which the serine residues at positions 32 and36 on that protein have been replaced with alanines. I ${kappa}$ B ${alpha}$ DN canno longer be phosphorylated and is consequently not proteolyzedupon treatment of cells with an NF- ${kappa}$ B-inducing agent (9). Thismutant efficiently retains NF- ${kappa}$ B in the cytoplasm, thus blockingits function as a regulator of transcription by preventing itfrom translocating to the nucleus (83). It can be seen fromthis experiment that expression of I ${kappa}$ B ${alpha}$ DN efficiently inhibitedLMP1-induced bfl-1 promoter transactivation in DG75 cells ina dose-dependent manner (Fig. 1B). The inhibitory action ofI ${kappa}$ B ${alpha}$ DN was not the result of inhibition of LMP1 expression frompEFCX-LMP1, as can be seen from Western blot analysis of LMP1levels in protein extracts from the transfected cells (Fig.1B). Similar observations were made in BL41 cells; however,a lower amount (5 µg) of pEFCXI ${kappa}$ B ${alpha}$ DN was required to achievecomplete inhibition of transactivation by LMP1 (data not shown).These results strongly suggest that activation of the bfl-1promoter by LMP1 is NF- ${kappa}$ B dependent. In DG75, overexpressionof I ${kappa}$ B ${alpha}$ DN also inhibited the basal level of bfl-1 promoter activity(30% decrease in the presence of 10.0 µg of pEFCX-I ${kappa}$ B ${alpha}$ DN),suggesting that the latter may be NF- ${kappa}$ B dependent, at least inpart, in this cell line. In control transfection experiments,NF- ${kappa}$ B activation was monitored with a known NF- ${kappa}$ B-dependent reporterconstruct (3Enh-Luc). In these cases, using DG75 and BL41 cells,luciferase values increased by factors of 4 and 8, respectively,when this vector was cotransfected with pEFCX-LMP1, and an efficientdose-dependent inhibition of activation was observed in bothcell lines in the presence of pEFCX-I ${kappa}$ B ${alpha}$ DN (data not shown).

Treatment of a variety of cell lines with the chemical agentphorbol-12-myristate 13-acetate (PMA), a well-known activatorof NF- ${kappa}$ B, has been shown to upregulate bfl-1 mRNA levels in BLcell lines (93). We therefore investigated whether PMA, whenused at the same concentration (10^-7 M) as that reported previously,could also activate the bfl-1 promoter. DG75 cells that hadbeen transfected with either 3Enh-Luc or -1374/+81-Luc weretreated with PMA, and luciferase activities were then determinedfrom transfected cell extracts as before. In this experiment,PMA treatment was seen to activate NF- ${kappa}$ B by approximately 3.5-fold(Fig. 1C). In the case of the bfl-1 promoter, PMA treatmentresulted in a 6.8-fold increase in bfl-1 promoter activity (Fig.1C). In both cases, promoter activation was demonstrated tobe NF- ${kappa}$ B dependent, since cotransfection with pEFCX-I ${kappa}$ B ${alpha}$ DN ledto a significant decrease in luciferase values (Fig. 1C). AnNF- ${kappa}$ B binding site in the bfl-1 promoter (5'-GGGGATTTACC-3' atpositions -833 to -823 relative to the transcription start site)has previously been shown by site-directed mutagenesis to beessential for activation by c-Rel in the HeLa cell line (123).To investigate whether this NF- ${kappa}$ B-binding motif played a rolein LMP1-associated transactivation, a second bfl-1 reporterconstruct was generated which differed from -1374/+81-Luc inthat it carried the same inactivating mutation in this particularmotif [1374/+81(m ${kappa}$ B-833)]. In transient-transfection assays,however, it can be seen that LMP1 activated the promoter fragmentson both of these constructs to a similar extent in DG75 cellsand that elimination of the NF- ${kappa}$ B-binding motif at -833/-823did not significantly affect the basal level of promoter activity(Fig. 1D), and the same result was achieved with BL41 (datanot shown). In addition, PMA treatment also activated the mutatedpromoter to the same extent as its unmutated counterpart inboth cell lines (Fig. 1D). The ensemble of these results clearlyindicated that the bfl-1 promoter is transactivated by LMP1in the EBV-negative BL cell lines used, that transactivationis NF- ${kappa}$ B dependent, and that the NF- ${kappa}$ B binding motif at position-833/-823 is not essential for activation of the promoter byLMP1 or PMA in this cell context.

LMP1-associated bfl-1 promoter activation is blocked by overexpression of A20 and occurs by a mechanism involving TRAF2. A20 is an antiapoptotic RING finger protein that interacts withTRAFs and efficiently inhibits NF- ${kappa}$ B and JNK activation by LMP1by displacing TRAF and TRADD molecules from LMP1-TRAF and LMP1-TRADDcomplexes (32, 34, 42). To investigate whether overexpressionof A20 could inhibit transactivation of the bfl-1 promoter byLMP1, cotransfections were performed as before with the inclusionof various amounts of an A20 expression vector (pSFFVA20). Itcan be seen that A20 expression potently inhibited bfl-1 promoteractivation by LMP1 in DG75 cells, with transfection of 5.0 and10.0 µg of pSFFVA20 resulting in approximately 80 and94% inhibition, respectively (Fig. 2A). A similar degree ofinhibition of NF- ${kappa}$ B activation was observed when using the 3Enh-Lucreporter (data not shown). A20 expression did not alter thebasal levels of bfl-1 promoter activity or endogenously activatedNF- ${kappa}$ B, suggesting that A20 only affected LMP1-induced signaling.In addition, A20 expression did not interfere with LMP1 levelsproduced from cotransfected vector as assessed by Western blottingof lysates prepared from the transfected cell populations (Fig.2A).

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FIG. 2. LMP1-associated bfl-1 promoter activation is blocked by overexpression of A20 and occurs by a mechanism involving TRAF2. DG75 cells were cotransfected with 2.5 µg of pEFCX-LMP1 or pEFCX and 2.5 µg of -1374/+81-Luc together with various amounts of plasmids expressing either A20 (0, 2.5, 5.0, or 10.0 µg of pSFFVA20) (A) or a dominant-negative mutant of TRAF2 [0, 5.0, or 10.0 µg of pcDNA3-TRAF2 ${Delta}$ (6-86)] (B). In each case, cells were harvested at 24 h posttransfection and analyzed for luciferase activity and LMP1 expression (shown below each graph), as described before. Normalized luciferase values were expressed as activation (n-fold) over the corresponding control empty vector.

TRAF2 has been shown to bind to the cytoplasmic tail of LMP1and is an important mediator of NF- ${kappa}$ B activation by LMP1. TRAF2binds directly to the CTAR1 domain of LMP1 and binds to CTAR2via the adaptor protein TRADD (58, 71, 103). The carboxyl-terminaldomain of TRAF2 mediates TRAF2-binding to the LMP1 CTAR1 domainand TRADD, whereas the amino-terminal RING finger-containingdomain is involved in homo- and heterodimerization of TRAF familymembers and binding to cellular inhibitors of apoptosis (c-IAPs)and is essential for TRAF2-mediated activation of NF- ${kappa}$ B and JNK(58, 71, 103). A dominant-negative mutant of TRAF2 [TRAF2 ${Delta}$ (6-86)],which has a deletion of amino acids 6 to 86 in the N-terminalregion, has been shown to inhibit activation of NF- ${kappa}$ B and JNKby LMP1 (32). To determine whether TRAF2 had a direct role inmediating LMP1-associated bfl-1 promoter activation, we useda vector that expresses TRAF2 ${Delta}$ (6-86) in transient cotransfectionassays. Coexpression of TRAF2 ${Delta}$ (6-86) was found to significantlyreduce bfl-1 promoter activation by LMP1 in a dose-dependentmanner in that 5.0 and 10 µg of pcDNA3-TRAF2 ${Delta}$ (6-86) decreasedLMP1-associated transactivation by 25 and 48%, respectively(Fig. 2B). Western blotting again showed that the inhibitoryeffect of TRAF2 ${Delta}$ (6-86) was not due to inhibition of LMP1 expression(Fig. 2B). The effect of TRAF2 ${Delta}$ (6-86) expression on LMP1-mediatedactivation of NF- ${kappa}$ B was also investigated with the 3Enh-Luc construct.In this experiment, cotransfection of 5 and 10 µg of pcDNA3-TRAF2 ${Delta}$ (6-86)resulted in decreases of 40 and 65%, respectively, in LMP1-mediatedactivation of NF- ${kappa}$ B (data not shown). Similar results were obtainedwith regard to both LMP1 activation of the bfl-1 promoter andactivation of NF- ${kappa}$ B with A20 and TRAF2 ${Delta}$ (6-86) in transfectionsof the BL41 cell line (data not shown). Taken together, theseresults implicate the involvement of TRAF2 in LMP1-mediatedtransactivation of the bfl-1 promoter in these cells.

Identification of LMP1 signaling domains required for induction of bfl-1 promoter activity. To identify the signaling domain(s) of LMP1 that are importantfor mediating bfl-1 promoter transactivation, plasmids expressingLMP1 molecules with amino acid substitutions at critical residuesin CTAR1 and CTAR2 were used in comparative analyses with wild-typeLMP1 in promoter-luciferase assays. Thus, LMPAAA contains atriple amino acid substitution in the CTAR1-TRAF interactiondomain (P²⁰⁴xQ²⁰⁶xT²⁰⁸ $->$ AxAxA) which has been shown to blockNF- ${kappa}$ B activation by this domain (26, 32, 34); LMPG contains asingle point mutation in CTAR2 such that the tyrosine residueat position 384 has been replaced with a glycine, a modificationthat potently inhibits activation of NF- ${kappa}$ B and AP-1 by inhibitingTRADD binding (34, 40); LMPAAAG contains the modifications fromboth LMPAAA and LMPG and is not able to activate NF- ${kappa}$ B or AP-1(8, 39). Both transactivation of the bfl-1 promoter and NF- ${kappa}$ Bactivation by wild-type and signaling-defective LMP1 proteinswere investigated by cotransfection of the corresponding pSG5-basedeffector plasmids with the -1374/+81-Luc and 3Enh-Luc constructs,respectively. It can be seen that expression of wild-type LMP1activated the bfl-1 and control NF- ${kappa}$ B-responsive promoters byapproximately 6.4- and 3.6-fold, respectively, in DG75 cells(Fig. 3A). In comparison, activation of both promoters by LMPAAAand LMPG achieved levels of approximately 75 and 20%, respectively,when compared to values obtained with wild-type LMP1. LMPAAAGwas effectively unable to activate either promoter (Fig. 3A).The observed effects were not due to differences in the levelsof wild-type and mutant LMP1 proteins expressed during transfection(Fig. 3B). These results show that the CTAR1 and CTAR2 domainsof LMP1 can independently contribute to bfl-1 promoter activation,with CTAR2 being the predominant contributor in this regard.Furthermore, both domains are required for maximal activationof the bfl-1 promoter and activation of NF- ${kappa}$ B. The relative contributionof the individual domains of LMP1 to inducing bfl-1 promoteractivity can be seen to correlate well with NF- ${kappa}$ B activation,suggesting again that the latter is a key event in mediatingthe effect of LMP1 on bfl-1.

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FIG. 3. Comparative analysis of the effects of wild-type and functionally mutated LMP1 molecules on bfl-1 promoter activity. (A) DG75 cells were cotransfected with 2.5 µg of either pSG5, pSG5-LMP1 (expressing wild-type LMP1), pSG5-LMPAAA (expressing LMP1 containing a nonfunctional CTAR1 domain), pSG5-LMPG (expressing LMP1containing a nonfunctional CTAR2 domain), or pSG5-LMPAAAG (expressing LMP1 mutant that is nonfunctional in both CTAR1 and CTAR2) and 2.5 µg of either -1374/+81-Luc or 3Enh-Luc. Cells were harvested at 24 h posttransfection and analyzed for luciferase activity. Normalized luciferase values were expressed as activation (n-fold) over control (empty vector), as described before. (B) Western blot analysis of the level of expression of wild-type and mutated LMP1 molecules in transient-transfection assays in DG75 cells; protein lysates were prepared from the transfection shown in panel A and loaded (lanes 1 to 5) in the same order as the corresponding expression vectors shown in that figure (only cell extracts from the cotransfections with -1374/+81-Luc are shown). A schematic representation of the LMP1 protein and signaling-deficient derivatives thereof is shown underneath. Mutations are indicated as X in the cytoplasmic signaling domains CTAR1/TES-1 and CTAR2/TES-2, which are labeled as 1 and 2, respectively.

Activation of CD40 receptor leads to increased bfl-1 mRNA levels and an NF- ${kappa}$ B-dependent increase in bfl-1 promoter activity in BL-derived cell lines. CD40 engagement on BL-derived cell lines has previously beenshown to lead to increased bfl-1 mRNA levels (82), but the mechanisminvolved has not yet been investigated. Here, Northern blotanalysis revealed that treatment of the Mutu I (EBV-positivelatency type 1) and BL41-B95.8 (EBV-positive latency type 3)cell lines with the agonistic anti-CD40 antibody G28.5 (20)resulted in increased bfl-1 mRNA levels (Fig. 4A). Both celllines express CD40 (data not shown), and in both cases, theeffect was transient with significant upregulation detectableby 8 h followed by a return to the level seen in untreated cellsby 24 h. The transient nature of this effect is consistent withobservations made elsewhere (82). In contrast, treatment ofthe BL cell line Rael with G28.5 did not lead to detectablelevels of bfl-1 mRNA (Fig. 4A). Although Rael expresses CD40,it has been shown by others to be unresponsive to several CD40-mediatedeffects on gene expression (54). A more detailed analysis ofthe kinetics of upregulation of bfl-1 mRNA by CD40 ligationwas performed with DG75 cells (Fig. 4B). In this experiment,it can be seen that an increase in the level of bfl-1 mRNA wasdetected as early as 4 h posttreatment with anti-CD40 antibody.This level was maintained for at least 12 h and then decreasedto near-basal levels by 24 h.

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FIG. 4. Activation of CD40 receptor leads to increased bfl-1 mRNA levels and an NF- ${kappa}$ B-dependent increase in bfl-1 promoter activity in BL-derived cell lines. Rael, Mutu I, BL41-B95.8 (A), and DG75 (B) cells were left untreated or were treated with the CD40 agonistic antibody G28.5 either as a 1:4,000 dilution of ascites (Rael, Mutu I, and BL41-B95.8) or at a concentration of 1 µg of purified antibody (DG75)/ml. Total RNA samples were prepared from cells at 0, 8, and 24 h (Rael, Mutu I, and BL41-B95.8) or at 0, 4, 8, 12, and 24 h (DG75) posttreatment and subjected to Northern blot analysis with an antisense bfl-1 riboprobe (upper panels of panels A and B). The blots were then sequentially stripped and rehybridized with antisense riboprobe to glyceraldehyde-3-phosphate dehydrogenase (GAPDH) mRNA (lower panels of both panels A and B). (C) LMP1 and CD40 cooperate in upregulating bfl-1 mRNA in DG75tTA-LMP1 cells. Uninduced DG75tTA-LMP1 cells or DG75tTA-LMP1 cells induced to express LMP1 (36 h after tetracycline removal) were either left untreated or stimulated with 1 µg of the anti-CD40 antibody G28.5/ml. Total RNA extracted from cells at 0, 4, and 8 h after stimulation with G28.5 was used in Northern blot analysis with an antisense bfl-1 riboprobe (upper panel). The blots were sequentially stripped and reprobed with a GAPDH riboprobe (lower panel). (D) Expression of a superrepressor I ${kappa}$ B ${alpha}$ mutant inhibits bfl-1 promoter upregulation after activation of CD40 in the presence (+) or absence (-) of LMP1. DG75 cells were cotransfected with 2.5 µg of pEFCX-LMP1 or pEFCX and 2.5 µg of -1374/+81-Luc in the absence or presence of 10.0 µg of pEFCX-I ${kappa}$ B ${alpha}$ DN. At 36 h posttransfection, the cells were either left untreated or were treated with 1 µg of G28.5/ml for 12 h prior to harvesting for measurement of luciferase activity. Normalized luciferase values are expressed as activation (n-fold) over that of the control (empty vector in the absence of expression of I ${kappa}$ B ${alpha}$ DN or absence of treatment with G28.5 equals 1).

To analyze the effect of dual signaling from LMP1 and CD40 onbfl-1 mRNA levels, we used a stable transfectant of DG75 inwhich LMP1 expression can be regulated by tetracycline (DG75tTA-LMP1)(38). Northern blotting was used to monitor bfl-1 mRNA levelsin DG75tTA-LMP1 cells before induction and at 36 h postinductionof LMP1 expression in the presence or absence of G28.5 (Fig.4C). As expected, induction of LMP1 resulted in a marked increasein the level of bfl-1 mRNA. A small but consistent further increasein bfl-1 mRNA levels was detectable at 4 and 8 h post-CD40 stimulationof LMP1-expressing cells. The minor effect of CD40 ligationon bfl-1 mRNA levels in the absence of LMP1 may be a reflectionof the low levels of CD40 expression in these cells (even lowerthan in untransfected DG75 cells) which are significantly elevatedupon induction of LMP1 (38; also data not shown). To determinewhether ligation of CD40 was leading to increased bfl-1 promoteractivity, DG75 cells that had been transfected with -1374/+81-Lucwere treated at 36 h posttransfection for a further 12 h withG28.5, and luciferase values were compared to those obtainedwith untreated transfected cells. In this experiment it canbe seen that (i) stimulation of CD40 led to a 2.2-fold increasein bfl-1 promoter activity, (ii) transactivation by LMP1 was3.4-fold, (iii) activation of CD40 in the presence of LMP1 ledto an overall 4.8-fold increase, and (iv) expression of I ${kappa}$ B ${alpha}$ DNwas seen to inhibit CD40-mediated promoter activation, indicatingthat the pathway is NF- ${kappa}$ B dependent (Fig. 4D). In this case,the extent of activation as a result of dual signaling fromCD40 and LMP1 is greater than that provided by each of the individualsignals but is less than that expected of an additive effectfrom both signals. These findings suggest that the signalingpathways initiated from CD40 and LMP1 may converge when it comesto driving the bfl-1 promoter. It is also possible, however,that part of the effect of CD40 activation is due to the increasedsurface expression of CD40 in LMP1-transfected cells. In addition,it cannot be excluded that the dual effect of LMP1 and CD40,which is also seen to be NF- ${kappa}$ B dependent, may be the result ofan indirect effect on the NF- ${kappa}$ B-mediated process of upregulatingthe level of CD40 (25). The lower extent of promoter activationby LMP1 in this experiment is likely to be due to the differencesin the time of harvesting of the transfected cells for reporterassays (106, 119).

A 210-bp bfl-1 promoter fragment (-129/+81) mediates NF- ${kappa}$ B-dependent transactivation by LMP1. To identify DNA sequence elements that mediate transactivationby LMP1, a series of reporter constructs was generated in whichprogressive deletions were introduced from the 5' end of thebfl-1 promoter sequence in -1374/+81-Luc (Fig. 5A). The abilityof LMP1 to transactivate these truncated promoter fragmentswas investigated by cotransfections with pEFCX-LMP1, as before,with the DG75 and BL41 cell lines. It can be seen that in DG75cells, LMP1 transactivated -1374/+81-Luc by a factor of 8.2and that considerable transactivation was retained by the promoterfragments -1240/+81, -367/+81-Luc, and -129/+81-Luc (6.5-, 6.2-,and 5.6-fold, respectively), with a further decrease to 3.3-foldobserved when only the -57/+81 promoter sequence was retained(Fig. 5B). The fact that similar transactivation values wereobserved with -1240/+81-Luc and -367/+81-Luc again indicatedthat the previously identified NF- ${kappa}$ B binding motif at position-833/-823 does not play a significant role in LMP1-associatedactivation of the promoter in this cell context. The observationthat -57/+81-Luc still retained a considerable degree of responsivenessto LMP1 (but significantly less than -129/+81-Luc) indicatedthat the -129 to -57 region of the promoter might contain DNAsequence elements that contributed to but were not essentialfor activation by LMP1. It can also be seen that coexpressionof I ${kappa}$ B ${alpha}$ DN efficiently inhibited LMP1-induced transactivation of-129/+81-Luc in a dose-dependent manner (Fig. 5C) (with thelevels of LMP1 expressed from pEFCX-LMP1 remaining constantin each transfection, as before) (data not shown). A significantNF- ${kappa}$ B-dependent response was also seen with PMA with the -129/+81-Lucconstruct (68% of the activity observed with -1374/+81-Luc),and in all cases, similar results were observed when BL41 cellswere used (data not shown). It can thus be concluded that the-129/+81 sequence from the bfl-1 transcriptional regulatoryregion contains DNA sequence elements that mediate a high proportionof the NF- ${kappa}$ B-dependent activation of this gene by LMP1 in theseBL-derived cell lines.

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FIG. 5. A 210-bp fragment (-129/+81) of the bfl-1 promoter is transactivated by LMP1 in an NF- ${kappa}$ B-dependent manner. (A) Schematic representation of bfl-1 promoter-reporter constructs in which the promoter sequence has been progressively deleted from the 5' end (coordinates of the 5' ends are given to the left of each construct). They all share a common 3' terminus 81 bp downstream from the transcription initiation site (designated by a bent arrow), at which point they are joined to the luciferase gene (LUC). The position of a previously identified NF- ${kappa}$ B site at position -833 is indicated on the plasmid -1374/+81-Luc as a black box. (B) DG75 cells were transfected with 2.5 µg of either pEFCX-LMP1 or pEFCX together with 2.5 µg of the individual bfl promoter-luciferase reporter constructs shown in panel A. Cells were harvested 24 h posttransfection and assayed for luciferase activity as described before. Normalized luciferase values were expressed as activation (n-fold) relative to the corresponding value obtained for each reporter construct when cotransfected with control pEFCX. (C) LMP1-mediated activation of the -129/+81 region of the bfl-1 promoter is inhibited by expression of a superrepressor I ${kappa}$ B ${alpha}$ mutant (I ${kappa}$ B ${alpha}$ DN) in DG75 cells. DG75 cells were cotransfected with 2.5 µg of pEFCX-LMP1 or pEFCX and 2.5 µg of -129/+81-Luc together with the indicated amounts of pEFCX-I ${kappa}$ B ${alpha}$ DN. Cells were harvested at 24 h posttransfection and analyzed for luciferase activity. Normalized luciferase values are given as activation (n-fold) over those of the controls (empty vector in the absence of expression of I ${kappa}$ B ${alpha}$ DN equals 1).

Identification of NF- ${kappa}$ B-like and AP-1-like binding sites on the bfl-1 promoter that mediate transactivation by LMP1. Using Transcription Element Search Software, we analyzed the-129/+81 region of the bfl-1 promoter for candidate sequenceelements that may bind transcription factors known to play arole in LMP1-mediated regulation of gene expression. One NF- ${kappa}$ B-likebinding site (5'-AGAAATTCCA-3' at -52 to -43) and two AP-1-likebinding sites (5'-CATGACATGAA-3' at -104 to -94 and 5'-AGTGACTAGGA-3'at -74 to -64) were identified in the region 5' to the transcriptioninitiation site (Fig. 6A). Base substitutions were then introducedinto the core of each of these motifs in the reporter plasmid-129/+81-Luc by site-directed mutagenesis to eliminate potentialbinding by the corresponding transcription factor (Fig. 6A).Transient transfections of these constructs with pSG5 or pSG5-LMP1were then carried out with DG75 cells. It can be seen that mutationof the NF- ${kappa}$ B-like binding site led to the nearly complete lossof transactivation by LMP1 (Fig. 6B), an effect that was reproducedwhen the same mutation was introduced into the promoter sequencein -1374/+81-Luc (Fig. 6C). Mutation of the AP-1-like bindingsite at -104/-94 did not impair transactivation (actually seento marginally increase), whereas elimination of the site at-74/-64 resulted in a significant decrease (reduced by 34%)in promoter activity in the presence of LMP1 (Fig. 6B). Thelatter result correlates with the observation of a similar reductionin LMP1-associated transactivation upon deletion of the -129to -57 region (Fig. 5B, compare -57/+81-Luc and -129/+81-Luc).

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FIG. 6. Identification of NF- ${kappa}$ B-like and AP1-like binding sites on the bfl-1 promoter that mediate transactivation by LMP1. (A) Schematic representation of -129 to + 1 region of the bfl-1 promoter showing the relative locations and sequences of candidate binding sites for relevant transcription factors. Three further reporter constructs were made by introducing base changes (underlined) to each of the sequences shown by site-directed mutagenesis, thus eliminating each candidate site in turn. The name of the corresponding vector which carries the individual mutation is given underneath. In panels B and C, DG75 cells were transfected with 1 µg of either pSG-LMP1 or pSG5 together with 1 µg of the individual bfl promoter-luciferase reporter constructs shown underneath each graph. An identical sequence change to that indicated in panel A was made to the NF- ${kappa}$ B-like motif (-52/-43) in the reporter construct with the longest bfl-1 promoter sequence available, thus generating -1374/+81m ${kappa}$ B(-52). Cells were harvested 24 h posttransfection and assayed for luciferase activity as described before. Normalized luciferase values were expressed as activation (n-fold) relative to the corresponding value obtained for each reporter construct when cotransfected with control pEFCX.

To determine whether sequences from this region of the bfl-1promoter could confer LMP1 responsiveness on a heterologouspromoter, portions of the -129/+1 sequence were subcloned upstreamof the minimal ß-globin promoter in the luciferasereporter construct pGa50.7 (Fig. 7A) (81). Transient cotransfectionsof these reporter plasmids with pSG5 or pSG5-LMP1 were thencarried out with DG75 cells, and the results of this experimentare shown in Fig. 7B. It can be seen that a fivefold increasein luciferase values was consistently obtained when the basalvector (pGa50.7) was cotransfected with pSG5-LMP1 but that thisincreased by a further factor of 8 when the -129/+1 sequencewas linked to the minimal promoter [Fig. 7B, compare pGa50-7and pGa(-129/+1)]. Deletion of up to 35 bp from the 3' end ofthe bfl-1 sequence, which still retained the NF- ${kappa}$ B-like and AP-1-likebinding sites, did not lead to any decrease in LMP1-associatedtransactivation [Fig. 7B, pGa(-129/-26) and pGa(-129/-34)].It can also be seen that a construct in which the -129/-34 sequencehad been inserted in the opposite orientation [pGa(-34/-129)]was transactivated by LMP1 at least as efficiently as pGa(-129/-34).However, deletion or mutation of the NF- ${kappa}$ B-like binding siteat -52/-43 led to the complete loss of LMP1-associated transactivation[pGa(-129/-54), pGa(-129/-34m ${kappa}$ B), and pGa(-34/-129m ${kappa}$ B)]. We concludethat the -129/-34 region of the bfl-1 promoter functions asan LMP1-dependent transcriptional enhancer and that the NF- ${kappa}$ B-likebinding site at position -52 to -43 is essential for this effect.

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FIG. 7. The NF- ${kappa}$ B-like binding site at -52/-43 is essential for conferring LMP1-responsiveness on a heterologous minimal promoter. (A) Schematic representation of luc reporter constructs generated after subcloning portions of the -129/+1 region of the bfl-1 promoter upstream of the ß-globin minimal promoter (checkered box with bent arrow) in pGa50.7. The name of each reporter construct includes the relevant 5' and 3' ends of the bfl-1 sequence. The mutation introduced into the NF- ${kappa}$ B-like site is indicated with an X. (B) DG75 cells were transfected with 1 µg of either pSG-LMP1 or pSG5 together with 1 µg of the luciferase reporter constructs as indicated underneath each graph. Cells were harvested at 24 h posttransfection and assayed for luciferase activity as described before. Normalized luciferase values were expressed as activation (n-fold) relative to the corresponding value obtained for each reporter construct when cotransfected with control pSG5.

Mutation of the NF- ${kappa}$ B-like binding site at -52/-43 reduces bfl-1 promoter transcriptional activation upon engagement of CD40 receptor. We then investigated whether the NF- ${kappa}$ B-like binding site at -52/-43in the bfl-1 promoter played a role in mediating transactivationby CD40. In these experiments, transiently transfected DG75cells were cocultivated with either a mouse fibroblast L cellline that stably expressed recombinant human CD40 ligand (CD40lig-Lcells), to activate CD40 signaling (43), or a human CD32/Fc-gRII(CD32-L cells)-expressing cell line, as a control (98). It canbe seen that engagement of the CD40 receptor on transfectedDG75 cells led to increases in luciferase values of approximately3.4-, 2.7-, and 2.0-fold, respectively, when the 3Enh-Luc, pGa(-129/-34),and -129/+81-Luc vectors were used as reporters (Fig. 8). Mutationof the NF- ${kappa}$ B-like binding site in both pGa(-129/-34) and -129/+81-Lucled to decreases of 66% ± 18% and 46% ± 5%, respectively,in the levels of promoter activity that were recorded upon engagementof CD40 receptor with CD40 ligand (Fig. 8). This experimentshowed that the NF- ${kappa}$ B-like binding site at -52/-43 plays a keyrole in CD40-mediated activation of the bfl-1 promoter. It alsoserved to corroborate the finding presented in Fig. 4D, in whichit is shown that bfl-1 promoter upregulation was triggered byan agonistic anti-CD40 antibody.

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FIG. 8. Mutation of the NF- ${kappa}$ B-like binding site at -52/-43 reduces bfl-1 promoter transcriptional activation upon engagement of CD40 receptor. DG75 cells were transfected with 2 µg of reporter construct (indicated underneath the graph) and then cultured for 24 h on either CD40lig-L cells or CD32-L cells, which express human CD40 ligand and human CD32/Fc-gRII, respectively. DG75 cells were then harvested and analyzed for luciferase activities which were normalized for transfection efficiency (based on ß-galactosidase activity measured from cotransfected pCMVlacZ reporter, which was included in all transfections). The absolute luciferase values obtained for 3Enh-Luc, pGa(-129/-34), and -129/+81-Luc after transfection and cocultivation with CD40lig-L cells were set at 100%. Percent values for pGa(-129/-34m ${kappa}$ B) and -129/+81m ${kappa}$ B are given relative to pGa(-129/-34) and -129/+81, respectively.

The NF- ${kappa}$ B-like binding site at -52/-43 mediates transactivation by the NF- ${kappa}$ B subunit protein p65 but not c-Rel. The subunit composition of NF- ${kappa}$ B can greatly influence not onlyits ability to bind to a particular DNA sequence motif but alsothe extent of promoter transactivation (99). To directly investigatethe ability of Rel family members to drive transcription fromthe bfl-1 promoter, transient cotransfections were thereforeperformed with DG75 cells with vectors that express individualNF- ${kappa}$ B subunit proteins. It can be seen that the pGa(-129/-34)reporter was transactivated approximately 3.0-fold (over pGa50-7)when cotransfected with p65 expression vector (Fig. 9A) andthat transactivation was completely abolished upon mutationof the NF- ${kappa}$ B-like binding site at -52/-43 [Fig. 9A, pGa(-129/-34m ${kappa}$ B)].Cotransfection of the same reporter with either a c-Rel or ap50 expression vector failed to significantly transactivatepGa(-129/-34) (Fig. 9A). It can also be seen that there wasa lack of any synergistic effect when either p65/p50 or p65/c-Relexpression vector combinations were cotransfected with the samereporter construct (Fig. 9A). Similar results were obtainedwith the -129/+81-Luc reporter, in that cotransfection of p65effector plasmid alone led to a significant increase (threefold)in bfl-1 promoter activity, and mutation of the NF- ${kappa}$ B-like bindingsite again led to the loss of transactivation by p65 (Fig. 9B).These experiments showed that p65 directly transactivated thebfl-1 promoter and that the NF- ${kappa}$ B-like binding site at -52/-43was essential both for this effect and also for conferring p65responsiveness on a heterologous minimal promoter in DG75 cells.

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FIG. 9. The NF- ${kappa}$ B-like binding site at -52/-43 mediates transactivation by the NF- ${kappa}$ B subunit protein p65 but not c-Rel. (A and B) DG75 cells were transfected with 2 µg of vector expressing various NF- ${kappa}$ B subunit proteins together with 1 µg of the luciferase reporter constructs indicated underneath each graph. Cells were harvested at 48 h posttransfection and assayed for luciferase activity as described before. Normalized luciferase values were expressed as activation (n-fold) relative to the corresponding value obtained for each reporter construct when cotransfected with control vector pcDNA3.1.

DISCUSSION

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Discussion

It was already shown that expression of LMP1 in EBV-negativeBL cell lines coincides with a dramatic increase in the levelof bfl-1 mRNA (30). Here, we show for the first time that LMP1transactivates the bfl-1 promoter in this cell context, andwe present evidence that points to a key role for NF- ${kappa}$ B in thisprocess. The implication of a role for NF- ${kappa}$ B is in keeping withother studies in which increases in bfl-1 mRNA levels have beendemonstrated in response to agents such as lipopolysaccharide,TNF- ${alpha}$ , or etoposide, all of which are known to lead to the activationof this transcription factor (60, 117, 123). NF- ${kappa}$ B inhibitionhas been associated with decreased bfl-1 mRNA levels in an LCL(11). Furthermore, ectopic expression of the NF- ${kappa}$ B subunit proteinsc-Rel and p65 (but not p50) was also shown to independentlyupregulate bfl-1 mRNA levels in HeLa cells, and in the caseof TNF- ${alpha}$ , this was demonstrated to be due to an increase in bfl-1promoter activity (123). In the same study, it was shown thatc-Rel transactivated the bfl-1 promoter through its interactionwith a consensus NF- ${kappa}$ B binding site at position at -833/-823relative to the known transcription start site of this gene.Elsewhere, the expression of mouse A1 (the murine bfl-1 homologue)was shown to be induced in response to mitogen stimulation ofprimary B cells in a c-Rel-dependent fashion (49).

In this study, the evidence of an important role for NF- ${kappa}$ B inthe regulation of bfl-1 promoter activity by LMP1 is based onseveral observations. First, coexpression of a superrepressorI ${kappa}$ B ${alpha}$ mutant inhibited transactivation. Second, inhibition of TRAF2-mediatedactivation of NF- ${kappa}$ B by either coexpression of a dominant-negativeTRAF2 molecule or overexpression of the TRAF2-binding zinc fingerprotein A20 impaired transactivation by LMP1. Third, treatmentwith PMA, a well-known activator of NF- ${kappa}$ B in many cell types,also stimulated bfl-1 promoter activity. Fourth, expressionof the NF- ${kappa}$ B subunit protein p65 transactivates the bfl-1 promoter.In all cases, the anticipated inhibitory or stimulatory effectsof these molecules were mirrored when monitored in parallelwith an NF- ${kappa}$ B-responsive reporter construct.

The loss of transactivation that is seen in response to TRAF2 ${Delta}$ (6-86)and A20 strongly implies that TRAF2 is a component of the signalingpathway involved in the activation of bfl-1 by LMP1. However,of the two, A20 was more efficient at inhibiting LMP1 activationof both the bfl-1 promoter and NF- ${kappa}$ B. Similar findings with theseTRAF2 inhibitors have been reported with other promoters instudies involving LMP1 and TNF- ${alpha}$ (32, 34, 58, 71, 100). In thecase of LMP1, TRAF2 ${Delta}$ (6-86) has been shown to only partially blockthe activation of NF- ${kappa}$ B by CTAR2 (40%) while almost completelyblocking that mediated by CTAR1 (>75%) (71). One interpretationof these observations is that although TRAF2 is a componentof the signaling pathway involved in the activation of bfl-1by LMP1, additional contributions from other CTAR1/2-associatedproteins, such as other TRAFs, may also be involved (26). Inthis regard, the receptor-interacting protein has also beenshown to interact directly with CTAR2 but does not mediate activationof NF- ${kappa}$ B and is therefore not a likely candidate for inclusionin this case (63). Alternatively, it is possible that TRAF2is bound in a stable complex with other proteins and that eitherinsufficient quantities of TRAF2 ${Delta}$ (6-86) were expressed or theposttransfection incubation period was not long enough to permitthe mutant to efficiently displace endogenous wild-type TRAF2.Indeed a number of TRAF2-interacting proteins have been identified,such as TRAF1, TANK/I-TRAF, and c-IAPs, which may affect TRAF2heterocomplexes in terms of their stability and signaling potential(for a review, see reference 36). Consistent with this possibilityis the observation that while CTAR1 can directly bind TRAF2,CTAR2 binds TRAF2 indirectly via TRADD (63). Hence, the differencesin the stoichiometry of binding of TRAF2 to these two domainsof LMP1 may account for the inefficiency of TRAF2 ${Delta}$ (6-86) inhibitionof TRAF2-mediated signaling from the predominant signaling domainCTAR2, relative to CTAR1. A20, a zinc finger protein whose expressionis induced by LMP1 in an NF- ${kappa}$ B-dependent manner, can inhibitboth LMP1-induced NF- ${kappa}$ B and JNK activation, thereby acting ina negative feedback loop to control LMP1 signaling. Such controlmay be important in that overexpression of LMP1 can have toxiceffects on the cell (42, 50, 86). Although this activity ofA20 was initially presumed to be dependent upon its interactionwith only TRAF2 (34), more-detailed studies suggest that A20can function as a promiscuous inhibitor of the activities ofother TRAFs and TRADD (42). In this context, the data presentedin this study do not rule out an additional role for other LMP1-interactingsignaling molecules in mediating activation of the bfl-1 promoter.

Several studies have indicated that CTAR1 and CTAR2 can independentlymediate activation of NF- ${kappa}$ B by LMP1; however, the extent of thecontribution of each of these domains to the total activationof NF- ${kappa}$ B varies between cell lines (40, 61, 92). In general,CTAR2 has been found to be a stronger activator of NF- ${kappa}$ B thanCTAR1. The NF- ${kappa}$ B-dependent upregulation of A20 expression byLMP1 maps to both the CTAR1 and CTAR2 domains, and the contributionof each domain to this effect correlates with the relative extentsof activation of NF- ${kappa}$ B by the two domains (89, 90). A third possibleactivation domain, CTAR3, mapping to a region between CTAR1and CTAR2 (residues 275 to 307) has been shown to mediate activationof JAK3 (45). In this study, we used LMP1 mutants that are defectivein signaling from either CTAR1 (LMPAAA) or CTAR2 (LMPG) or bothof these domains together (LMPAAAG) to show that both of thesedomains are required for maximal activation of the bfl-1 promoterin EBV-negative BL-derived cell lines. LMPAAAG has already beenshown to function as a dominant-negative mutant and can efficientlyinhibit the activation of NF- ${kappa}$ B, JAK3, and Jun transcriptionalactivity by wild-type LMP1 (8). This mutant functions by interactingwith wild-type LMP1 and interfering with its ability to bindTRAF2. The requirement for cooperation between the CTAR1 andCTAR2 domains on different LMP1 molecules within the same hetero-oligomericcomplex is likely to form the basis for the high efficiencywith which LMPAAAG can inhibit LMP1-mediated signaling. In thisregard, only one LMPAAAG molecule within the oligomeric complex,which is at least trimeric, may be required to alter signalingfrom the complex (39, 40). Consistent with these findings, weobserved that LMPAAAG can efficiently inhibit wild-type LMP1-mediatedactivation of the bfl-1 promoter and NF- ${kappa}$ B in DG75 cells (datanot shown).

The observation that the double mutation in CTAR1 and CTAR2completely eliminates LMP1-mediated activation of the bfl-1promoter does not necessarily exclude a role for CTAR3 (or JAK3),since the function of CTAR3 may be dependent on CTAR1 and/orCTAR2 (8). The existence of a cooperative function between CTAR1and CTAR2 cautions against overinterpretation of data obtainedwith mutants nonfunctional for CTAR1 or CTAR2 but particularlywith mutants containing large deletions that may adversely affectphysical cooperation between CTAR1 and CTAR2 (26, 108).

An important aspect of CD40 signaling in B cells is its abilityto control apoptosis. Isolated germinal center cells, whichspontaneously undergo apoptosis in culture, are capable of survivingfor extended periods when treated with anti-CD40 antibodiesor CD40 ligand (4, 72). In addition, CD40 is known to rescueimmature B cells and mature B cells from surface IgM and Fas-mediatedapoptosis (47). Several studies have indicated that the antiapoptoticfunction of CD40 is mediated by upregulation of bcl-xL and A20(82, 109, 113). The results presented in this study supportthe addition of bfl-1 to this list. Our finding that Rael cellsdo not show increased bfl-1 mRNA levels in response to CD40activation is in accordance with the findings of others in thatthis latency type 1 BL-derived cell line is nonresponsive toCD40 activation with respect to other parameters as well (54).It has already been reported that activation of CD40 coincideswith a transient increase in bfl-1 mRNA levels in B lymphoma-derivedcell lines (22, 82). Here, we corroborate these findings andadditionally show that signaling through CD40 receptor, whentriggered either by engagement with its ligand or through cross-linkingwith an anti-CD40 antibody, leads to transactivation of thebfl-1 promoter by an NF- ${kappa}$ B-dependent pathway.

If LMP1 and CD40 utilize different signaling pathways to transactivatethe bfl-1 promoter, then at least an additive effect would havebeen expected. The finding of a less than additive effect butgreater than an individual effect of signaling from the twomembrane molecules can be interpreted to mean that both LMP1and CD40 share components of the same signaling pathway. Bothmembrane proteins have been reported to cooperate in an additiveor synergistic manner in upregulating cell surface moleculessuch as B7.1 and IgM as well as in the induction of IL-6 secretionin mouse B cell lines (10). However, although CD40 and LMP1could individually induce ICAM-1 and LFA-1 expression, a clearcooperative effect was not evident in that study. In BL-derivedcell lines, dual signaling from CD40 and LMP1 has been shownnot to result in a cooperative effect on the induction of anNF- ${kappa}$ B reporter construct in transient-transfection assays (39).Thus, cooperation between CD40 and LMP1 in regulating gene expressionmay not be a global phenomenon. At the mRNA level, it is furthercomplicated by the fact that LMP1 can upregulate CD40 expressionin BL-derived cell lines. Furthermore, it has already been shownthat bfl-1 mRNA is more stable in BL cell lines with a latencygroup 3 phenotype and that this effect is mediated at leastin part by LMP1 (30). However, our subsequent half-life studiesshowed no evidence of an increase in the stability of this transcriptfollowing the treatment of the EBV-negative BL cell line BJABwith G28.5 antibody (data not shown). This cell line has detectablelevels of bfl-1 transcript in the absence of CD40 activation.This result was somewhat surprising, since mRNA stabilizationis an effect that is often found associated with genes thatshow a rapid response to signals that modulate gene expression(14). It remains possible, however, that the lack of an effectof CD40 activation on bfl-1 mRNA stability may be specific tothis cell line.

We have demonstrated for the first time that that the -129/-34region of the bfl-1 promoter can function as an LMP1-dependenttranscriptional enhancer in EBV-negative BL-derived cell lines.Furthermore, we have shown that transactivation of this enhancerby LMP1 is NF- ${kappa}$ B dependent. Subsequent deletion and mutationalanalyses lead to the conclusion that a novel NF- ${kappa}$ B-like bindingsite at position -52 to -43 is essential for transactivationby LMP1 and also implicate a significant role for a nearby AP-1-likebinding site (-74/-64). Mutation of the NF- ${kappa}$ B-like binding sitein the context of a 1.4-kb bfl-1 promoter fragment led to thenearly complete loss of transactivation by LMP1. Classic NF- ${kappa}$ B(p65/p50) binds the sequence 5'-GGGRNNYYCC-3', whereas the RelA/cReldimer binds to the sequence 5'-HGGARNYYCC-3' (H indicates A,C, or T; R is purine [A or G]; and Y is pyrimidine [T or C])(6). The ${kappa}$ B-like site at position -52/-43 on the bfl-1 promoterdiffers from the p65/p50 and p65/c-Rel consensus binding sitesat nucleotide positions 3 and 2, respectively. NF- ${kappa}$ B-like sitesthat diverge from the consensus have been identified in thepromoters of several apoptosis-related genes such as bcl-x,c-IAP1, c-IAP2, and mouse A1 as well as cytokine genes suchas IL-8, and the functionality of these sites in promoter activationhas been demonstrated in several of these cases (15, 49, 57,94). Significantly, the -52/-43 site on the bfl-1 promoter is100% complementary to a CD28-responsive ${kappa}$ B site in the IL-2 promoter(18, 19, 115) and both c-Rel and p65 have been shown to playroles in mediating this response (44).

We have not been able to detect the interaction of NF- ${kappa}$ B subunitproteins with the NF- ${kappa}$ B-like binding site at -52/-43 in electrophoreticmobility shift assays (EMSA). In control experiments, however,p65-containing complexes were detectable when a probe whichcontained the ${kappa}$ B enhancer element from the Ig( ${kappa}$ ) light chain genewas incubated with nuclear protein extracts from DG75 cells(no EMSA data are shown). The presence of p65 was confirmed,as preincubation of nuclear extracts with anti-p65 antibodyled to the supershifting of specific DNA-protein complexes.This finding is consistent with the high constitutive levelsof activated NF- ${kappa}$ B known to be present in this cell context (61,106). When nuclear protein extracts from DG75-tTA-LMP1 wereused, the induction of LMP1 led to increases in the levels ofthese two p65-containing complexes without the formation ofany new complex. When various DNA fragments (ranging in sizefrom 14 bp up to the complete -129/+81 fragment) that encompassedthe bfl-1 -52/-43 sequence motif were used as probes, however,neither the profile nor the intensity of DNA-protein complexformation was altered in response to LMP1 induction. If NF- ${kappa}$ Bsubunits do bind to this motif in vivo, then our inability todetect binding in vitro may be the result of a low-affinityinteraction due to the fact that it is not a consensus NF- ${kappa}$ B-bindingsite. LMP1-associated upregulation may then be occurring bythe phosphorylation of a weakly bound p65-containing complex.In this regard, IL-1 (a member of the TNFR superfamily) hasbeen shown to stimulate the transactivation potential of p65by inducing the phosphorylation of its transactivation domainvia a phosphoinositide-3-OH kinase-Akt-dependent pathway (85,110), and the latter has recently been shown to be activatedby LMP1 (24). Alternatively, NF- ${kappa}$ B-associated transactivationof the bfl-1 promoter in DG75 and BL41 may be indirect and mediatedby a transcription factor that is induced or activated by NF- ${kappa}$ Band which failed to bind under the EMSA conditions used.

A sole NF- ${kappa}$ B DNA binding motif (-833/-823) has previously beenimplicated in regulating the c-Rel-dependent transactivationof the bfl-1 promoter in the epithelial cell line HeLa (123).More recently, chromatin immunoprecipitation assays showed thatthe in vivo interaction of c-Rel and p50 (but not p65) withthis site promotes the cooperative binding of C/EBPßand AP-1 in an enhanceosome-like complex in PMA-ionomycin-treatedJurkat T cells (31). We observed that in the context of DG75or BL41 cells, removal of this site by deletion or mutationdid not affect LMP1-associated activation of the bfl-1 promoter.Although it is clear that LMP1 activates different subsets ofNF- ${kappa}$ B subunit proteins in a cell-type dependent manner (16, 55,96), c-Rel is known to be activated by LMP1 in a lymphocytecellular context, including DG75 cells (16, 83). In additionto being nonresponsive to LMP1, we observed that this NF- ${kappa}$ B-bindingsite does not play a role in mediating transactivation of bfl-1by either PMA or p65 in EBV-negative BL-derived cell lines.This, coupled with the fact that c-Rel failed to activate luciferaseexpression via the -52/-43 site, may indicate that p65, andnot c-Rel, is the predominant subunit involved in regulatingthe bfl-1 promoter in EBV-negative BL cell lines in responseto LMP1. The failure of LMP1 to transactivate via the -833/-823site might therefore be due to its low affinity for p65. Itis also possible, however, that access to this site may be obstructedin EBV-negative BL-derived cell lines by lymphocyte-specificnuclear proteins binding in its vicinity.

LMP1-associated signaling also activates the JNK pathway, whichresults in the induction of the transcription factor AP1. Wehave shown that an AP1-like binding site at -74 to -64 alsoplays a role in LMP1-mediated transactivation of the bfl-1 promoter.However, in this case, the contribution of this sequence motifis dependent on the NF- ${kappa}$ B-like binding site at -52/-43, sinceany promoter fragments that lack the latter are not responsiveto LMP1. It has also been shown that the mitogen-activated proteinkinase p38 and NF- ${kappa}$ B contribute to the transactivation of certainLMP-1-inducible genes, such as IL-6, IL-8, and IL-10, throughcoregulation of their promoter sequences (33, 116). In a preliminaryexperiment, however, a well-established and specific inhibitorof p38 activation (SB203580) (112) did not affect transactivationof the bfl-1 promoter by LMP1 in DG75 cells (result not shown).

In lymphoid follicles, the bfl-1 transcript has been detectedin the germinal centers which are the sites for B-cell proliferationand differentiation (66). CD40 activation is necessary for rescuinggerminal center B cells from spontaneous apoptosis, and long-livedB cells are distinguished by elevated expression of bfl-1 (111).In this regard, Bfl-1 might be viewed as a key determinant ofcell fate for immature peripheral B cells. The strong inductionof bfl-1 transcripts by proinflammatory cytokines in endothelial,leukemic, and hemopoietic cells is consistent with a role forprotecting them from apoptotic extinction (17, 67, 68, 84, 93).Consistent with a role for NF- ${kappa}$ B in this process is the reductionin constitutive bfl-1 mRNA levels in B cell lines derived fromc-Rel^-/- mice (49). The ability of LMP1 to provide cell survivalsignals by upregulating the expression of antiapoptotic membersof the bcl-2 family of proteins, including bfl-1, is very significantfrom the standpoint of the mechanism of persistence of EBV inthe memory B cell in peripheral blood. In vivo, EBV-positivetonsillar memory B cells express a restricted pattern of latentgene transcripts which resembles the pattern of latent geneexpression detected in EBV-associated tumors (3). The actionsof LMP1 and LMP2A provide the surrogate T-cell help and B-cellreceptor signals that memory B cells require for long-term survival(12). Since BL lines exhibit phenotypic features reminiscentof germinal center B cells, and as Bfl-1 was shown previouslyto cooperate with the adenovirus E1A protein in inducing celltransformation (28, 29), the NF- ${kappa}$ B-dependent activation of bfl-1by LMP1 may be a key event in the rescue of EBV-infected B cellsfrom apoptosis and an important route by which LMP1 functionsin oncogenesis.

ACKNOWLEDGMENTS

We gratefully acknowledge the following gifts of plasmids: pEFCX,pEFCX-LMP1, and pEFCX-IkB ${alpha}$ DN from P. Brodin; pcDNA3TRAF2 ${Delta}$ (6-86)and pSFFVA20 from L. Young and A. Eliopoulos. The anti-CD40monoclonal antibody G28.5 was a generous gift from E. Clark.We are grateful to P. Garrone for the CD40lig-L and CD32-L celllines. We thank P. Cahill, K. Fitzgerald, and P. Brennan forhelpful discussions and advice.

This work was supported by a research grant from the HealthResearch Board (HRB; Dublin, Ireland) (D.W.). We also acknowledgesupport from National Institutes of Health grant CA83937 (C.G.).B.N.D. was supported by a postdoctoral fellowship from EnterpriseIreland.

FOOTNOTES

* Corresponding author. Mailing address: School of Biotechnology, Dublin City University, Dublin 9, Ireland. Phone: 353 1 7045600. Fax: 353 1 7045412. E-mail: Dermot.Walls{at}dcu.ie.

Present address: Department of Biological Chemistry, UCLA Schoolof Medicine, UCLA, Los Angeles, CA 90095-1737.

Present address: Department of Pathology, Children's Hospital,Harvard Medical School, Boston, MA 02115.

Present address: Schering-Plough (Brinny) Co., Innishannon,County Cork, Ireland.

^|| Present address: Max Delbrueck Center, Berlin, Germany.

REFERENCES

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