Notch1IC partially replaces EBNA2 function in B cells immortalized by Epstein-Barr virus.

Immortalization of B cells by Epstein-Barr virus (EBV) depends on the virally encoded EBNA2 protein. Although not related by sequence, the cellular Notch protein and EBNA2 share several biochemical and functional properties, such as interaction with CBF1 and the ability to activate transcription of a number of cellular and viral genes. Whether these similarities are coincidental or exemplify EBNA2 mimicry of evolutionarily conserved cellular signaling pathways is unclear. We therefore investigated whether activated forms of Notch could substitute for EBNA2 in maintaining the immortalized phenotype of EBV-infected B cells. To address this question, we devised a transcomplementation system using EREB2.5 cells. EREB2.5 cells are immortalized by EBV expressing a conditional estrogen receptor EBNA2 fusion protein (EREBNA2), and cellular proliferation is dependent on the availability of estrogen. Withdrawal of estrogen results in inactivation of EREBNA2, leading to growth arrest and eventually to cell death. Transduction of EREB2.5 cells with a lentiviral vector expressing wild-type EBNA2 rescued EREB2.5 cells from the growth-inhibitory effects of estrogen deprivation, in contrast to transduction with the lentivirus vector alone. EREB2.5 cells were also rescued by enforced expression of human Notch1IC after estrogen starvation, but this effect was restricted to cells expressing high levels of the transcription factor. Compared to wild-type EBNA2-expressing EREB2.5 cells, the Notch-expressing cells expanded more slowly after estrogen starvation, and once established, they continued to display a lower proliferation rate. Analysis of viral and cellular gene expression from transduced EREB2.5 cells after estrogen withdrawal indicated that both wild-type EBNA2- and Notch1IC-positive cells expressed c-Myc at levels similar to those found in parental EREB2.5 cells. However, the latter cells expressed LMP-1 far less efficiently than cells transduced with the wild-type EBNA2 gene. Cells rescued by either wild-type EBNA2 or Notch1IC expressed surface CD21 and CD23 proteins, but not CD10, indicating that induction of relevant type III latency markers was maintained. The data imply that both Notch and EBNA2 activate an important subset of cellular genes associated with type III latency and B-cell growth, while EBNA2 more efficiently induces important viral genes, such as LMP-1. Thus, exploitation of conserved Notch-related signaling pathways may represent a key mechanism by which EBNA2 contributes to EBV-induced cell immortalization.

Conserved regions in the Epstein-Barr virus leader protein define distinct domains required for nuclear localization and transcriptional cooperation with EBNA2.

Epstein-Barr virus (EBV) EBNA-LP is a latent protein whose function is not fully understood. Recent studies have shown that EBNA-LP may be an important EBNA2 cofactor by enhancing EBNA2 stimulation of the latency C and LMP-1 promoters. To further our understanding of EBNA-LP function, we have introduced a series of mutations into evolutionarily conserved regions and tested the mutant proteins for the ability to enhance EBNA2 stimulation of the latency C and LMP-1 promoters. Three conserved regions (CR1 to CR3) are located in the repeat domains that are essential for the EBNA2 cooperativity function. In addition, three serine residues are also well conserved in the repeat domains. Clustered alanine mutations were introduced into CR1 to CR3, and the conserved serines were also changed to alanine residues in an EBNA-LP with two repeats, which is the minimal protein able to cooperate with EBNA2. Mutations introduced into CR1a had no effect on EBNA-LP function, while mutations introduced into CR1b resulted in EBNA-LP with slightly decreased activity. Mutations in CR1c and CR2 resulted in proteins that no longer localized exclusively to the nucleus and also had no EBNA2 cooperation activity. Mutations introduced into conserved serines S5/71 resulted in proteins with slightly higher activity, while mutations introduced into conserved serines S35/101 or in CR3 (which contains S60/126) resulted in EBNA-LP proteins with substantially reduced activity. The potential karyophilic signals within EBNA-LP CR1c and CR2 were also examined by introducing oligonucleotides encoding these positively charged amino acid groupings into a cytoplasmic test protein, herpes simplex virus DeltaIE175, and by examining the intracellular localization of the resulting proteins. This assay identified a strong nuclear localization signal between EBNA-LP amino acids 43 and 50 (109 to 117 in the second W repeat) comprising CR2, while EBNA-LP amino acids 29 to 36 (91 to 98 in the second W repeat) were unable to function independently as a nuclear localization signal. However, a combination of amino acids 29 to 50 resulted in more efficient nuclear localization than with amino acids 43 to 50 alone. These results indicate that EBNA-LP has a bipartite nuclear localization signal and that efficient nuclear localization is essential for EBNA2 cooperativity function. Interestingly, EBNA-LP with only a single repeat localized exclusively to the cytoplasm, providing an explanation for why this isoform has no activity. In addition, two conserved serine residues which are distinct from nuclear import functions are important for EBNA2 cooperativity function.

Regulation of the Epstein-Barr virus C promoter by AUF1 and the cyclic AMP/protein kinase A signaling pathway.

EBNA2 is an Epstein-Barr virus (EBV)-encoded protein that regulates the expression of viral and cellular genes required for EBV-driven B-cell immortalization. Elucidating the mechanisms by which EBNA2 regulates viral and cellular gene expression is necessary to understand EBV-induced B-cell immortalization and viral latency in humans. EBNA2 targets to the latency C promoter (Cp) through an interaction with the cellular DNA binding protein CBF1 (RBPJk). The EBNA2 enhancer in Cp also binds another cellular factor, C promoter binding factor 2 (CBF2), whose protein product(s) has not yet been identified. Within the EBNA2 enhancer in Cp, we have previously identified the DNA sequence required for CBF2 binding and also determined that this element is required for efficient activation of Cp by EBNA2. In this study, the CBF2 activity was biochemically purified and microsequenced. The peptides sequenced were identical to the hnRNP protein AUF1. Antibodies against AUF1 but not antibodies to related hnRNP proteins reacted with CBF2 in gel mobility shift assays. In addition, stimulation of the cellular cyclic AMP (cAMP)/protein kinase A (PKA) signal transduction pathway results in an increase in detectable CBF2/AUF1 binding activity extracted from stimulated cells. Furthermore, the CBF2 binding site was able to confer EBNA2 responsiveness to a heterologous promoter when transfected cells were treated with compounds that activate PKA or by cotransfection of plasmids expressing a constitutively active catalytic subunit of PKA. EBNA2-mediated stimulation of the latency Cp is also increased in similar cotransfection assays. These results further support an important role for CBF2 in mediating EBNA2 transactivation; they identify the hnRNP protein AUF1 as a major component of CBF2 and are also the first evidence of a cis-acting sequence other than a CBF1 binding element that is able to confer responsiveness to EBNA2.

Sequence and functional analysis of EBNA-LP and EBNA2 proteins from nonhuman primate lymphocryptoviruses.

The Epstein-Barr virus (EBV) EBNA-LP and EBNA2 proteins are the first to be synthesized during establishment of latent infection in B lymphocytes. EBNA2 is a key transcriptional regulator of both viral and cellular gene expression and is essential for EBV-induced immortalization of B lymphocytes. EBNA-LP is also important for EBV-induced immortalization of B lymphocytes, but far less is known about the functional domains and cellular cofactors that mediate EBNA-LP function. While recent studies suggest that serine phosphorylation of EBNA-LP and coactivation of EBNA2-mediated transactivation are important, more detailed mutational and genetic studies are complicated by the repeat regions that comprise the majority of the EBNA-LP sequence. Therefore, we have used a comparative approach by studying the EBNA-LP homologues from baboon and rhesus macaque lymphocryptoviruses (LCVs) (baboon LCV and rhesus LCV). The predicted baboon and rhesus LCV EBNA-LP amino acid sequences are 61 and 64% identical to the EBV EBNA-LP W1 and W2 exons and 51% identical to the EBV EBNA-LP Y1 and Y2 exons. Five evolutionarily conserved regions can be defined, and four of eight potential serine residues are conserved among all three EBNA-LPs. The major internal repeat sequence also revealed a highly conserved Wp EBNA promoter with strong conservation of upstream activating sequences important for Wp transcriptional regulation. To test whether transcriptional coactivating properties were common to the rhesus LCV EBNA-LP, a rhesus LCV EBNA2 homologue was cloned and expressed. The rhesus LCV EBNA2 transcriptionally transactivates EBNA2-responsive promoters through a CBF1-dependent mechanism. The rhesus LCV EBNA-LP was able to further enhance rhesus LCV or EBV EBNA2 transactivation 5- to 12-fold. Thus, there is strong structural and functional conservation among the simian EBNA-LP homologues. Identification of evolutionarily conserved serine residues and regions in EBNA-LP homologues provides important clues for identifying the cellular cofactors and molecular mechanisms mediating these conserved viral functions.

Evolution of two types of rhesus lymphocryptovirus similar to type 1 and type 2 Epstein-Barr virus.

Rhesus monkeys and other nonhuman Old World primates are naturally infected with lymphocryptoviruses (LCV) that are closely related to Epstein-Barr virus (EBV). A rhesus LCV isolate (208-95) was derived from a B-cell lymphoma in a simian immunodeficiency virus-infected rhesus macaque. The EBNA-2 homologues from 208-95 and a previous rhesus LCV isolate (LCL8664) were polymorphic on immunoblotting, so the EBNA-2 genes from these two rhesus LCV were cloned, sequenced, and compared. The EBNA-2 genes have 40% nucleotide and 41% amino acid identities, and the differences are similar to those between the type 1 and type 2 EBV EBNA-2. Sequence from a portion of the LMP1 gene which is extremely divergent among different LCV was virtually identical between the 208-95 and LCL8664 strains, confirming a common rhesus LCV background. Thus, the EBNA-2 polymorphism defines the presence of two different rhesus LCV types, and both rhesus LCV types were found to be prevalent in the rhesus monkey population at the New England Regional Primate Research Center. The existence of two rhesus LCV types suggests that the selective pressure for the evolution of two LCV types is shared by human and nonhuman primate hosts.

Three unrelated viral transforming proteins (vIRF, EBNA2, and E1A) induce the MYC oncogene through the interferon-responsive PRF element by using different transcription coadaptors.

Kaposi sarcoma-associated herpesvirus vIRF is a viral transcription factor that inhibits interferon signaling and transforms NIH 3T3 cells, but does not bind interferon-stimulated response element (ISRE) DNA sequences. Here we show that induction of the MYC protooncogene is required for cell transformation by vIRF, and that vIRF increases MYC transcription up to 15-fold through specific promoter interactions at an ISRE sequence called the plasmacytoma repressor factor (PRF) element. These effects are resistant to cycloheximide but are inhibited by a dominant-negative ISRE-binding protein, indicating that vIRF acts together with a cellular cofactor at the PRF element to directly transactivate MYC. The coadaptor CREB-binding protein (CBP) binds vIRF and synergizes transactivation of MYC, but, unexpectedly, closely related histone acetyltransferases p300 and P/CAF potently suppress vIRF transactivation. On the basis of the prediction that other interferon-inhibiting viral transforming proteins behave similarly, we found that Epstein-Barr virus-induced nuclear antigen 2 (EBNA2) also binds p300/CBP, and that both EBNA2 and adenovirus E1A transactivate MYC through the PRF element. For E1A, P/CAF coactivates MYC, whereas both p300 and CBP suppress E1A transactivation. For EBNA2, both P/CAF and CBP coactivate the MYC promoter, whereas p300 suppresses EBNA2 transactivation. These findings demonstrate that viral transforming proteins can activate as well as inhibit transcription through coadaptor interactions. At some promoters CBP and p300 have previously unrecognized, competitive antagonism to each other. While all three viral proteins target the same promoter element, each has a different coadaptor use profile. These findings are consistent with cellular MYC repression playing a role in innate immunity as well as in control of cell proliferation.

Transcriptional activation signals found in the Epstein-Barr virus (EBV) latency C promoter are conserved in the latency C promoter sequences from baboon and Rhesus monkey EBV-like lymphocryptoviruses (cercopithicine herpesviruses 12 and 15).

The Epstein-Barr virus (EBV) EBNA2 protein is a transcriptional activator that controls viral latent gene expression and is essential for EBV-driven B-cell immortalization. EBNA2 is expressed from the viral C promoter (Cp) and regulates its own expression by activating Cp through interaction with the cellular DNA binding protein CBF1. Through regulation of Cp and EBNA2 expression, EBV controls the pattern of latent protein expression and the type of latency established. To gain further insight into the important regulatory elements that modulate Cp usage, we isolated and sequenced the Cp regions corresponding to nucleotides 10251 to 11479 of the EBV genome (-1079 to +144 relative to the transcription initiation site) from the EBV-like lymphocryptoviruses found in baboons (herpesvirus papio; HVP) and Rhesus macaques (RhEBV). Sequence comparison of the approximately 1,230-bp Cp regions from these primate viruses revealed that EBV and HVP Cp sequences are 64% conserved, EBV and RhEBV Cp sequences are 66% conserved, and HVP and RhEBV Cp sequences are 65% conserved relative to each other. Approximately 50% of the residues are conserved among all three sequences, yet all three viruses have retained response elements for glucocorticoids, two positionally conserved CCAAT boxes, and positionally conserved TATA boxes. The putative EBNA2 100-bp enhancers within these promoters contain 54 conserved residues, and the binding sites for CBF1 and CBF2 are well conserved. Cp usage in the HVP- and RhEBV-transformed cell lines was detected by S1 nuclease protection analysis. Transient-transfection analysis showed that promoters of both HVP and RhEBV are responsive to EBNA2 and that they bind CBF1 and CBF2 in gel mobility shift assays. These results suggest that similar mechanisms for regulation of latent gene expression are conserved among the EBV-related lymphocryptoviruses found in nonhuman primates.

Characterization of the CBF2 binding site within the Epstein-Barr virus latency C promoter and its role in modulating EBNA2-mediated transactivation.

The Epstein-Barr virus (EBV) EBNA2 protein is a transcriptional activator that regulates viral and cellular gene expression and is also essential for EBV-driven immortalization of B lymphocytes. The EBNA2-responsive enhancer in the viral latency C promoter (Cp) binds two cellular factors, CBF1 and CBF2. The precise role of the CBF2 protein for Cp enhancer function is presently unclear. CBF2 does not appear to interact with EBNA2 and binds just downstream of CBF1 between positions -339 and -368 in the Cp EBNA2 enhancer. Within this region an 8-bp sequence, CAGTGCGT, can be found, and a similar sequence is also located downstream of CBF1 binding sites in other EBNA2-responsive promoters. Previous studies have indicated that mutations and methylation in this sequence affect EBNA2 responsiveness. To investigate the requirements for CBF2 binding, we synthesized a series of oligonucleotides carrying double transversion mutations spanning both the conserved core sequence and outside flanking sequences. Surprisingly, mutations outside of the conserved core sequence in 4 bases immediately flanking the 5' end, GGTT, had the most deleterious effect on CBF2 binding. Mutations in the conserved core had a gradient effect, with those near the 5' end having the most deleterious effects on CBF2 binding. In addition, the affinities of CBF2 for binding to the LMP-1, LMP-2, and CD23 promoters were also measured. These promoters contain the conserved core but lack the 5' flanking GGTT motif and bound CBF2 weakly or not at all. Using Cp reporter plasmids containing CBF2 mutant binding sites, we were also able to show that at lower doses of EBNA2, Cp transactivation required a functional CBF2 binding site but that higher doses of EBNA2 transactivated CBF2 mutant promoters to 40% of wild-type levels. These assays indicate that CBF2 is important for EBNA2-mediated transactivation of the viral latency Cp. In addition, CBF2 activity was found to be associated with two polypeptides of 27 and 33 kDa.

Transcriptional activation of the Epstein-Barr virus latency C promoter after 5-azacytidine treatment: evidence that demethylation at a single CpG site is crucial.

The Epstein-Barr Virus (EBV) latency C promoter (Cp) is the origin of transcripts for six viral proteins. The promoter is active in lymphoblastoid B-cell lines but silent in many EBV-associated tumors and tumor cell lines. In these latter cell lines, the viral episome is hypermethylated in the vicinity of this promoter. We show that in such a cell line (Rael, a Burkitt's lymphoma line), 5-azacytidine inhibits DNA methyltransferase, brings about demethylation of EBV genomes, activates Cp transcription, and induces the expression of EBNA-2. Investigation of the phenomenon demonstrates the importance of the methylation status of a particular CpG site for the regulation of the Cp: (i) genomic sequencing shows that this site is methylated when the Cp is inactive and is not methylated when the promoter is active; (ii) methylation or transition mutation at this site abolishes complex formation with a cellular binding activity (CBF2) as determined by electrophoretic mobility shift analyses, competition binding analyses, and DNase I footprinting; and (iii) a single C --> T transition mutation at this site is associated with a marked reduction (> 50-fold) of transcriptional activity in a reporter plasmid. Thus, the CBF2 binding activity is shown to be methylation sensitive and crucial to EBNA-2-mediated activation of the Cp.

Contribution of conserved amino acids in mediating the interaction between EBNA2 and CBF1/RBPJk.

The Epstein-Barr virus EBNA2 protein is a transcriptional activator that achieves promoter specificity through interaction with the cellular DNA-binding protein CBF1/RBPJk. Within the amino acid 252-to-425 EBNA2 domain that targets CBF1/RBPJk lie three amino acid clusters, conserved regions (CR) 5, 6, and 7, that are retained in the Epstein-Barr virus type A and type B and herpesvirus papio proteins. To further define the important features of the targeting domain, we constructed EBNA2 polypeptides containing deletions in the targeting domain and double or triple point mutations in the conserved motifs. The ability of these polypeptides and the type B and herpesvirus papio domains to interact with CBF1/RBPJk was examined by performing electrophoretic mobility shift assays and correlated with the effect of the mutations on EBNA2 transactivation. Both human type B EBNA2 and herpesvirus papio EBNA2 bound CBF1/RBPJk efficiently. Mutation of hydrophobic residues in CR6 severely impaired CBF1/RBPJk interaction and transactivation, while mutation of CR5 led to a moderate decrease in both activities. Mutation of CR7 had only a minor effect. Synthetic peptides corresponding to each of the conserved motifs were also used as competitors in an electrophoretic mobility shift assay. Only the peptide representing CR6 (amino acids 318 to 327), and not a version of this peptide mutated at the tryptophan residues at positions 323 and 324 (WW323,324), could compete for EBNA2 complex formation with CBF1/RBPJk. Overall, the data indicated that CR5 contributes to an optimal interaction, perhaps through stabilizing contacts, while CR6 forms a crucial interface with CBF1/RBPJk. The peptide competition data are consistent with direct contacts between WW323,324 and CBF1/RBPJk.

EBNA-2 upregulation of Epstein-Barr virus latency promoters and the cellular CD23 promoter utilizes a common targeting intermediate, CBF1.

The EBNA-2 protein is essential for the establishment of a latent Epstein-Barr virus (EBV) infection and for B-cell immortalization. EBNA-2 functions as a transcriptional activator that modulates viral latency gene expression as well as the expression of cellular genes, including CD23. We recently demonstrated that EBNA-2 transactivation of the EBV latency C promoter (Cp) is dependent on an interaction with a cellular DNA-binding protein, CBF1, for promoter targeting. To determine whether targeting via CBF1 is a common mechanism for EBNA-2-mediated transactivation, we have examined the requirements for activation of the cellular CD23 promoter. Binding of CBF1 to a 192-bp mapped EBNA-2-responsive region located at position -85 bp to -277 bp upstream of the CD23 promoter was detected in electrophoretic mobility shift assays. The identity of the bound protein as CBF1 was established by showing that the bound complex was competed for by the CBF1 binding site from the EBV Cp, that the bound protein could be supershifted with a bacterially expressed fusion protein' containing amino acids 252 to 425 of EBNA-2 but was unable to interact with a non-CBF1-binding EBNA-2 mutant (WW323SR), and that in UV cross-linking experiments, the Cp CBF1 binding site and the CD23 probe bound proteins of the same size. The requirement for interaction with CBF1 was demonstrated in a transient cotransfection assay in which the multimerized 192-bp CD23 response region was transactivated by wild-type EBNA-2 but not by the WW323SR mutant. Reporter constructions carrying multimerized copies of the 192-bp CD23 response region or multimers of the CBF1 binding site from the CD23 promoter were significantly less responsive to EBNA-2 transactivation than equivalent constructions carrying a multimerized region from the Cp or multimers of the CBF1 binding site from the Cp. Direct binding and competition assays using 30-mer oligonucleotide probes representing the individual CBF1 binding sites indicated that CBF1 bound less efficiently to the CD23 promoter and the EBV LMP-1 promoter sites than to the Cp site. To investigate the basis for this difference, we synthesized a series of oligonucleotides carrying mutations across the CBF1 binding site and used these as competitors in electrophoretic mobility shift assays. The competition experiments indicated that a central core sequence, GTGGGAA, common to all known EBNA-2-responsive elements, is crucial for CBF1 binding. Flanking sequences on either side of this core influence the affinity for CBF1.(ABSTRACT TRUNCATED AT 400 WORDS)

Mediation of Epstein-Barr virus EBNA2 transactivation by recombination signal-binding protein J kappa.

The Epstein-Barr virus (EBV) transactivator protein, termed Epstein-Barr virus nuclear antigen 2 (EBNA2), plays a critical role in the regulation of latent viral transcription and in the immortalization of EBV-infected B cells. Unlike most transcription factors, EBNA2 does not bind directly to its cis-responsive DNA element but requires a cellular factor, termed C-promoter binding factor 1 (CBF1). Here, CBF1 was purified and was found to directly interact with EBNA2. CBF1 is identical to a protein thought to be involved in immunoglobulin gene rearrangement, RBPJ kappa. Contrary to previous reports, CBF1-RBPJ kappa did not bind to the recombination signal sequences but instead bound to sites in the EBV C-promoter and in the CD23 promoter.

The Epstein-Barr virus immortalizing protein EBNA-2 is targeted to DNA by a cellular enhancer-binding protein.

The Epstein-Barr virus nuclear antigen EBNA-2 is essential for Epstein-Barr virus-induced immortalization of B cells. EBNA-2 is a transcriptional activator capable of modifying the expression of specific viral and cellular genes. However, the mechanism of EBNA-2 transactivation has been an enigma. We used a fractionated extract of CA46 lymphoblastoid cells and bacterially expressed EBNA-2 polypeptides to demonstrate that EBNA-2 is targeted to the Epstein-Barr virus latency C promoter (Cp) through interaction with a cellular DNA binding protein designated Cp binding factor 1 (CBF1). A glutathione S-transferase-EBNA-2 fusion protein containing aa 252-425 of EBNA-2 interacted with CBF1 to yield a slowly migrating complex in an electrophoretic mobility shift assay. Mutation of EBNA-2 aa 323 and 324, which lie within a highly conserved amino acid motif, abolished the interaction with CBF1. This same mutation also abolished the ability of EBNA-2 to activate the Cp in a cotransfection assay. The binding site for CBF1 was localized to residues -359 to -388 of the Cp by using an electrophoretic mobility shift assay and DNase I footprinting. Introduction of multiple copies of the CBF1 binding site upstream of a minimal heterologous promoter conferred EBNA-2 responsiveness on that promoter. Mutation of a core sequence CNGTGGGAA abolished CBF1 binding, and the mutated sequence was unable to mediate EBNA-2 transactivation. The CBF1 core sequence also occurs in other EBNA-2-responsive promoters suggesting that CBF1 may mediate EBNA-2 transactivation of both cellular and viral targets.

EBNA-2 of herpesvirus papio diverges significantly from the type A and type B EBNA-2 proteins of Epstein-Barr virus but retains an efficient transactivation domain with a conserved hydrophobic motif.

EBNA-2 contributes to the establishment of Epstein-Barr virus (EBV) latency in B cells and to the resultant alterations in B-cell growth pattern by up-regulating expression from specific viral and cellular promoters. We have taken a comparative approach toward characterizing functional domains within EBNA-2. To this end, we have cloned and sequenced the EBNA-2 gene from the closely related baboon virus herpesvirus papio (HVP). All human EBV isolates have either a type A or type B EBNA-2 gene. However, the HVP EBNA-2 gene falls into neither the type A category nor the type B category, suggesting that the separation into these two subtypes may have been a recent evolutionary event. Comparison of the predicted amino acid sequences indicates 37% amino acid identity with EBV type A EBNA-2 and 35% amino acid identity with type B EBNA-2. To define the domains of EBNA-2 required for transcriptional activation, the DNA binding domain of the GAL4 protein was fused to overlapping segments of EBV EBNA-2. This approach identified a 40-amino-acid (40-aa) EBNA-2 activation domain located between aa 437 and 477. Transactivation ability was completely lost when the amino-terminal boundary of this domain was moved to aa 441, indicating that the motif at aa 437 to 440, Pro-Ile-Leu-Phe, contains residues critical for function. The aa 437 boundary identified in these experiments coincides precisely with a block of conserved sequences in HVP EBNA-2, and the comparable carboxy-terminal region of HVP EBNA-2 also functioned as a strong transcriptional activation domain when fused to the Gal4(1-147) protein. The EBV and HVP EBNA-2 activation domains share a mixed proline-rich, negatively charged character with a striking conservation of positionally equivalent hydrophobic residues. The importance of the individual amino acids making up the Pro-Ile-Leu-Phe motif was examined by mutagenesis. Any alteration of these residues was found to reduce transactivation efficiency, with changes at the Pro-437 and Phe-440 positions producing the most deleterious effects. Activation of the EBV latency C promoter by EBNA-2 was shown to be dependent on the presence of the carboxy-terminal activation domain. However, this requirement was generic, rather than specific, since the EBNA-2 activation domain could be replaced with those from the herpes simplex virus (HSV) VP16 protein or the EBV Rta protein. Potential karyophilic signals within EBNA-2 were examined by introducing oligonucleotides encoding positively charged amino acid groupings that might serve in this capacity into a cytoplasmic test protein, HSV delta IE175, and by examining the intracellular localization of the resulting proteins. This assay identified a strong nuclear localization signal between EBV amino acids (aa) 478 to 485, which was conserved in HVP, and a weaker noncanonical signal between EBV aa 341 to 355, which was not conserved in HVP.

Antagonistic effect of interferon-beta on the interferon-gamma-induced expression of Ia antigen in murine macrophages.

The cell surface expression of I region-associated (Ia) antigens by murine and human macrophages has been shown by investigators from a number of laboratories to be induced in a dose-dependent fashion by IFN-gamma, which is free of other lymphokines. The experiments described in this report demonstrate that fibroblast-derived IFN-beta exerts an antagonistic effect on IFN-gamma induced Ia expression in murine macrophages. Simultaneous addition of IFN-beta and IFN-gamma to peritoneal exudate macrophages results in decreased Ia expression when compared with macrophages treated with IFN-gamma only. Different sources of highly purified IFN-beta, as well as a recombinant human IFN-alpha (A/D Bgl; shown previously to be as active as IFN-beta in several other murine systems) acted in a similar antagonistic fashion to IFN-gamma-induced Ia induction. The down-regulation of Ia expression by IFN-beta is dose-dependent over a concentration range up to 100 U/ml. Time-course experiments indicated that for IFN-beta to down-regulate IFN-gamma-induced Ia, it had to be present either before stimulation with IFN-gamma or during the first 24 hr of simultaneous stimulation. Further experiments in which a highly specific antibody against IFN-alpha/beta was added to the cultures confirmed the findings of the time-course experiments. Inhibitors of the arachidonic acid pathway failed to reverse the effect of IFN-beta to reduce Ia antigen expression, which suggests that this inhibition is not prostaglandin mediated. Thus, these findings support a role for type I IFN as naturally occurring substances that negatively regulate the expression of class II molecules.