A chimera of EBNA1 and the estrogen receptor activates transcription but not replication

Methylation patterns of papillomavirus DNA, its influence on E2 function, and implications in viral infection

The biological activities of the papillomavirus E2 protein in transcription, replication, and maintenance of the papillomavirus genome rely on the E2 protein's ability to bind that genome specifically. The E2 binding sites (E2BSs), located within the long control region (LCR) of human papillomavirus (HPV) genomes, contain potential sites for 5'methylation at cytosine (CpG) residues. The E2 protein's capacity to bind E2BS in vitro is inhibited by methylation of these cytosines (59). Herein, we describe experiments to assess the influence of methylation on E2 function in cells. E2's ability to activate transcription was inhibited by the global methylation of CpG dinucleotides in E2-responsive transcriptional templates or when only the CpG dinucleotides within the E2BSs of a transcriptional template were methylated. Thus at least one biological activity of E2 that is dependent on its ability to bind DNA in a site-specific manner is influenced by the methylation status of its cognate binding site. The activity of DNA methylases is influenced by the differentiation status of mammalian cells. The life cycle of HPVs is tied to the differentiation of its host cells within stratified squamous epithelia. To investigate whether methylation of the papillomavirus genomes is influenced by the differentiation status of host epithelial cells, we analyzed HPV16 DNA harvested from a cervical epithelial cell line that was isolated from an HPV16-infected patient. We found, using bisulfite treatment to discriminate between methylated and unmethylated cytosines, that the HPV16 LCR was selectively hypomethylated in highly differentiated cell populations. In contrast, the HPV16 LCR from poorly differentiated, basal cell-like cells contained multiple methylated cytosines and were often methylated at E2BSs, particularly E2BS(2). These experiments indicate that the methylation state of the viral genome, and particular that of E2BSs, may vary during the viral life cycle, providing a novel means for modulating E2 function. These studies also uncovered an extensive pattern of methylation at non-CpG dinucleotides indicative of de novo methylation. The potential implications of this de novo methylation pattern are discussed.

Latency-associated nuclear antigen (LANA) cooperatively binds to two sites within the terminal repeat, and both sites contribute to the ability of LANA to suppress transcription and to facilitate DNA replication

The latency-associated nuclear antigen (LANA) of Kaposi's sarcoma-associated herpesvirus is a multifunctional protein with important roles in both transcriptional regulation and episomal maintenance. LANA is also a DNA-binding protein and has been shown to specifically bind to a region within the terminal repeat. Here, we have performed a detailed analysis of the DNA-binding activity of LANA and show that it binds two sites separated by 22 bp. We used electrophoretic mobility shift assay to quantitatively analyze the binding sites and determined that the K(d) of the high affinity site is 1.51 +/- 0.16 nm. Examination of the contribution of nucleotides near the ends of the site showed that the core binding site consists of 16 bp, 13 of which are conserved between both sites. Analysis of the affinity of each site alone and in tandem revealed that the binding to the second site is primarily due to cooperativity with the first site. Using deletion and point mutations, we show that both sites contribute to the ability of LANA to suppress transcription and to facilitate DNA replication. In addition, we show that the ability of LANA to carry out these functions is directly proportional to its affinity for the sites in this region. The affinities, spacing, and cooperative binding between the two sites is similar to that of the Epstein-Barr virus dyad symmetry element oriP, suggesting a requirement for such an element in latent replication of these related DNA tumor viruses.

Human p32: a coactivator for Epstein-Barr virus nuclear antigen-1-mediated transcriptional activation and possible role in viral latent cycle DNA replication

The Epstein-Barr virus (EBV) nuclear antigen-1 (EBNA-1) is required for the maintenance of the viral chromosome in latently infected, proliferating cells and plays a role in latent cycle DNA replication. EBNA-1 also functions as a positive and negative regulator of EBV gene expression. We have investigated the interaction of EBNA-1 with p32, a host mitochondrial protein that associates with EBNA-1 in EBV-positive Burkitt's lymphoma cells. Using a chromatin immunoprecipitation assay, we found that a fraction of p32 localizes to the viral latent cycle origin of DNA replication oriP in vivo. p32 binds EBNA-1 independently of other proteins or DNA. EBNA-1 variants lacking one of two p32 binding elements did not interact stably with p32 in cultured cells and were defective for both transcriptional activation of a reporter gene linked to oriP FR and replication and/or maintenance of a plasmid bearing oriP. These results support a role for p32 in transcriptional activation by EBNA-1 and suggest that p32 plays a role in EBV latent cycle DNA replication.

Rep*: a viral element that can partially replace the origin of plasmid DNA synthesis of Epstein-Barr virus

Replication of the Epstein-Barr viral (EBV) genome occurs once per cell cycle during latent infection. Similarly, plasmids containing EBV's plasmid origin of replication, oriP, are replicated once per cell cycle. Replication from oriP requires EBV nuclear antigen 1 (EBNA-1) in trans; however, its contributions to this replication are unknown. oriP contains 24 EBNA-1 binding sites; 20 are located within the family of repeats, and 4 are found within the dyad symmetry element. The site of initiation of DNA replication within oriP is at or near the dyad symmetry element. We have identified a plasmid that contains the family of repeats but lacks the dyad symmetry element whose replication can be detected for a limited number of cell cycles. The detection of short-term replication of this plasmid requires EBNA-1 and can be inhibited by a dominant-negative inhibitor of EBNA-1. We have identified two regions within this plasmid which can independently contribute to this replication in the absence of the dyad symmetry element of oriP. One region contains native EBV sequences within the BamHI C fragment of the B95-8 genome of EBV; the other contains sequences within the simian virus 40 genome. We have mapped the region contributing to replication within the EBV sequences to a 298-bp fragment, Rep*. Plasmids which contain three copies of Rep* plus the family of repeats support replication more efficiently than those with one copy, consistent with a stochastic model for the initiation of DNA synthesis. Plasmids with three copies of Rep* also support long-term replication in the presence of EBNA-1. These observations together indicate that the latent origin of replication of EBV is more complex than formerly appreciated; it is a multicomponent origin of which the dyad symmetry element is one efficient component. The experimental approach described here could be used to identify eukaryotic sequences which mediate DNA synthesis, albeit inefficiently.

An imperfect correlation between DNA replication activity of Epstein-Barr virus nuclear antigen 1 (EBNA1) and binding to the nuclear import receptor, Rch1/importin alpha

Epstein-Barr virus (EBV) replicates as a stable multicopy episome in latently infected mammalian cells. Latent cycle DNA replication requires only two viral elements, the cis-acting origin of plasmid replication (oriP) and the trans-acting origin binding protein (EBNA1). EBNA1 binds multiple recognition sites in oriP, but has not other enzymatic activities associated with replication functions. To identify human cellular proteins that mediate EBNA1 function, we designed a one-hybrid assay in yeast to select for proteins that bind to EBNA1 when bound to criP in vivo. A human cDNA encoding the Rch1/hSRP1 alpha/ importin alpha protein was isolated and shown to bind to full-length EBNA1, but not to an amino terminal deletion mutant of EBNA1 when bound to oriP in yeast. The interaction of EBNA1 with Rch1 was confirmed biochemically by coimmunoprecipitation from nuclear extracts and by direct binding of recombinant proteins in vitro. Internal deletion mutations in EBNA1 which compromised DNA replication activity were similarly reduced for binding to Rch1. Mutations with no effect on DNA replication activity were similarly unaffected for Rch1 binding. Rch1/importin alpha has been shown to bind to the nuclear localization sequence (NLS) of several proteins and stimulate nuclear import. A substitution mutation in the EBNA1 nuclear localization sequence reduced Rch1 binding, but had no effect on DNA replication function, indicating that Rch1 binding affinity does not correspond precisely with replication activity. Nevertheless, the identification of a stable interaction between Rch1 and EBNA1 at the origin of viral DNA replication raises the intriguing possibility that Rch1 contributes to the nuclear functions of EBNA1.

Dominant-negative inhibitors of EBNA-1 of Epstein-Barr virus

Epstein-Barr virus (EBV) nuclear antigen 1 (EBNA-1) is required in trans to support replication of the EBV genome once per cell cycle via the latent origin of replication, oriP. EBNA-1 can also activate transcription on binding to the family of repeats of oriP to enhance some heterologous as well as native EBV promoters. We have made and screened derivatives of EBNA-1 for the ability to act as inhibitors of wild-type EBNA-1. These derivatives lack the linking or the retention functions of EBNA-1 and were analyzed for the residual ability to activate transcription and replication. We have identified derivatives of EBNA-1 that can inhibit up to 98% of wild-type EBNA-1's activities. We have also identified one derivative of EBNA-1 with only two of EBNA-1's three linking domains which can support transcription and replication inefficiently.

A system utilizing Epstein-Barr virus-based expression vectors for the functional cloning of human fibroblast growth regulators

The acquired ability of adherent mammalian cells to grow in suspension is closely linked to tumorigenic transformation. The anchorage-independence phenotype is likely to result from bypassing an adherence-responsive cell-cycle check-point at the G1/S boundary of the cell cycle. In order to identify genes that are part of or act upon the anchorage signal transduction pathway, we have developed a system which allows functional cloning of regulatory genes by expression of libraries of cDNA inserts either in the sense or antisense direction. The system is comprised of two components: (i) the library expression vectors, CMV-EL and C1E-EL, containing EBoriP for replication in EBN A-1-expressing cells, an expression cassette with a multiple cloning site suitable for directional insertion of cDNA libraries generated by standard protocols, and loxP sites which allow rapid manipulation of recovered vectors without the use of restriction enzymes and (ii) the EBNA-1-producing cell line, BB-5, a derivative of the immortalized, non-tumorigenic and anchorage-dependent human fibroblast cell line, MSU1.1. The growth characteristics of BB-5 cells did not differ from its parental cell line. BB-5 cells supported the episomal replication of CMV-EL and C1E-EL and allowed recovery of the vector from Hirt lysates of transfected BB-5 cells. BB-5 cells transformed to anchorage-independent growth by transfection with a mutant c-Ha-ras gene inserted into CMV-EL could be accurately and efficiently identified in a background of non-transfected BB5 cells by screening for anchorage-independent colonies with the aid of computer-assisted image analysis.

Plasmid maintenance of derivatives of oriP of Epstein-Barr virus

oriP is the origin of plasmid replication of Epstein-Barr virus. Replication from oriP requires both the cis-acting elements (the family of repeats and the dyad symmetry element) and the viral origin-binding protein, EBNA-1. The ability of plasmids containing oriP to be maintained stably in EBNA-1-positive cells reflects the efficiency both of their replication and of their segregation each cell cycle. The efficiency of plasmid maintenance was determined for plasmids containing derivatives of oriP with one copy of the dyad symmetry element and two copies of the family of repeats by measuring the rate at which they were lost from cells in the absence of selection. These measurements demonstrated that plasmids with derivatives of oriP with two copies of the family of repeats in one orientation are maintained only slightly less efficiently than is wild-type oriP. To determine whether plasmid maintenance could be affected by reinitiation at the dyad symmetry element (T. A. Gahn and C. L. Schildkraut, Cell 58:527-535, 1989), plasmids containing derivatives of oriP with two copies of the dyad symmetry element and one copy of the family of repeats were compared with plasmids containing wild-type oriP in EBNA-1-positive cells. These measurements showed that plasmids containing a derivative of oriP with two copies of the dyad symmetry element are maintained as efficiently as is wild-type oriP and are not amplified relative to wild-type oriP. These observations indicate that the trans-acting factors that regulate DNA to replicate once per S phase are insensitive to multiple cis-acting regulatory sites within a replicon.

Retention of plasmid DNA in mammalian cells is enhanced by binding of the Epstein-Barr virus replication protein EBNA1

The capacity to bind the Epstein-Barr viral protein EBNA1 increases the retention of the plasmid in dividing cells. This retention requires binding of multiple EBNA1 molecules for function, although significant retention activity is seen with fewer EBNA1 binding sites than are required to activate replication or transcription. The regions of EBNA1 that are required for increased plasmid retention overlap with those required for activation of transcription and replication. The similarities in traits of EBNA1 that are required for support of DNA replication and retention of plasmid DNA indicate that both may be mediated by interactions with an overlapping set of cellular proteins.

Cell fusion induced by the murine leukemia virus envelope glycoprotein

To determine whether ecotropic murine leukemia virus (MuLV) envelope glycoproteins are sufficient to cause cell-to-cell fusion when expressed in the absence of virus production, we used an ecotropic MuLV, AKV, to construct env expression vectors that lack the gag and pol genes. The rat cell line XC, which undergoes cell-to-cell fusion upon infection with ecotropic MuLV, was transfected with wild-type env expression vectors, and high levels of syncytium formation resulted. Transfection of the murine cell line NIH 3T3 with expression vectors containing the wild-type or mutated env region did not result in syncytium formation. Immunoprecipitation analysis of the envelope glycoproteins expressed in NIH 3T3 and XC cells showed that the mature surface glycoprotein expressed in XC cells was of a much lower apparent molecular weight than that expressed in NIH 3T3 cells. Further characterization showed that most if not all of this difference was the result of differences in glycosylation. Finally, site-directed mutagenesis was used to introduce several conservative and nonconservative changes into the amino-terminal region of the transmembrane protein. Analysis of the effect of these mutations confirmed that this region is a fusion domain.