The minimal replicator of Epstein-Barr virus oriP

oriP is a 1.7-kb region of the Epstein-Barr virus (EBV) chromosome that supports the replication and stable maintenance of plasmids in human cells. oriP contains two essential components, called the DS and the FR, both of which contain multiple binding sites for the EBV-encoded protein, EBNA-1. The DS appears to function as the replicator of oriP, while the FR acts in conjunction with EBNA-1 to prevent the loss of plasmids from proliferating cells. Because of EBNA-1's role in stabilizing plasmids through the FR, it has not been entirely clear to what extent EBNA-1 might be required for replication from oriP per se, and a recent study has questioned whether EBNA-1 has any direct role in replication. In the present study we found that plasmids carrying oriP required EBNA-1 to replicate efficiently even when assayed only 2 days after plasmids were introduced into the cell lines 143B and 293. Significantly, using 293 cells it was demonstrated that the plasmid-retention function of EBNA-1 and the FR did not contribute significantly to the accumulation of replicated plasmids, and the DS supported efficient EBNA-1-dependent replication in the absence of the FR. The DS contains two pairs of closely spaced EBNA-1 binding sites, and a previous study had shown that both sites within either pair are required for activity. However, it was unclear from previous work what additional sequences within the DS might be required. We found that each "half" of the DS, including a pair of closely spaced EBNA-1 binding sites, had significant replicator activity when the other half had been deleted. The only significant DNA sequences that the two halves of the DS share in common, other than EBNA-1 binding sites, is a 9-bp sequence that is present twice in the "left half" and once in the "right half." These nonamer repeats, while not essential for activity, contributed significantly to the activity of each half of the DS. Two thymines occur at unique positions within EBNA-1 binding sites 1 and 4 at the DS and become sensitive to oxidation by permanganate when EBNA-1 binds, but mutation of each to the consensus base, adenine, actually improved the activity of each half of the DS slightly. In conclusion, the DS of oriP is an EBNA-1-dependent replicator, and its minimal active core appears to be simply two properly spaced EBNA-1 binding sites.     

Establishment of an oriP replicon is dependent upon an infrequent, epigenetic event

Plasmids containing oriP, the latent origin of replication for Epstein-Barr virus, support efficient replication in selected cell clones when the viral protein EBNA-1 is provided, being lost at a rate of 2 to 4% per cell generation after removal of selection (A. L. Kirchmaier and B. Sugden, J. Virol. 69:1280-1283, 1995; B. Sugden and N. Warren, Mol. Biol. Med. 5:85-94, 1988). We refer to these plasmids as established replicons in that they support efficient DNA synthesis and partitioning each cell cycle. Unexpectedly, we have found that upon introduction of oriP plasmids into a population of EBNA-1-positive cells, oriP plasmids replicate but are lost precipitously from cells during 2 weeks posttransfection (>25% rate of loss per cell generation). Upon investigation of these disparate observations, we have found that only 1 to 10% of cells transfected with an oriP plasmid expressing EBNA-1 and hygromycin phosphotransferase give rise to drug-resistant clones in which the oriP replicon is established. A hereditable alteration in these drug-resistant cell clones, manifested at the genetic or epigenetic level, does not underlie the establishment of oriP, as newly introduced oriP plasmids replicate but are also lost rapidly from these cells. In addition, a genetic alteration in the oriP plasmid is not responsible for establishment, as oriP plasmids isolated from an established cell clone, propagated in Escherichia coli, and reintroduced into EBNA-1-positive cells are likewise established inefficiently. Our findings demonstrate that oriP replicons are not intrinsically stable in EBNA-1-positive cell lines. Rather, the establishment of an oriP replicon is conferred upon the replicon by a stochastic, epigenetic event that occurs infrequently and, therefore, is detected in only a minority of cells.     

The plasmid replicon of EBV consists of multiple cis-acting elements that facilitate DNA synthesis by the cell and a viral maintenance element.

Plasmids containing oriP, the plasmid origin of Epstein-Barr virus (EBV), are replicated stably in human cells that express a single viral trans-acting factor, EBNA-1. Unlike plasmids of other viruses, but akin to human chromosomes, oriP plasmids are synthesized once per cell cycle, and are partitioned faithfully to daughter cells during mitosis. Although EBNA-1 binds multiple sites within oriP, its role in DNA synthesis and partitioning has been obscure. EBNA-1 lacks enzymatic activities that are present in the origin-binding proteins of other mammalian viruses, and does not interact with human cellular proteins that provide equivalent enzymatic functions. We demonstrate that plasmids with oriP or its constituent elements are synthesized efficiently in human cells in the absence of EBNA-1. Further, we show that human cells rapidly eliminate or destroy newly synthesized plasmids, and that both EBNA-1 and the family of repeats of oriP are required for oriP plasmids to escape this catastrophic loss. These findings indicate that EBV's plasmid replicon consists of genetic elements with distinct functions, multiple cis-acting elements that facilitate DNA synthesis and viral cis/trans elements that permit retention of replicated DNA in daughter cells. They also explain historical failures to identify mammalian origins of DNA synthesis as autonomously replicating sequences.     

Initiation of DNA replication within oriP is dispensable for stable replication of the latent Epstein-Barr virus chromosome after infection of established cell lines

The 165-kb circularized chromosome of Epstein-Barr virus (EBV) is replicated in latently infected cells once per cell cycle by host proteins during S phase. Replication initiates at multiple sites on latent EBV chromosomes, including within a 1.8-kb region called oriP, which can provide both replication and stabilization for recombinant plasmids in the presence of the EBV-encoded protein, EBNA-1. Replication initiates at or near the dyad symmetry component (DS) of oriP, which depends on multiple EBNA-1 binding sites for activity. To test the importance of the replication function of oriP, the DS was deleted from the viral genome. EBV mutants lacking the DS and carrying a selectable gene could establish latent infections in BL30 cells, in which circular, mutant viral chromosomes were stably maintained. Analysis of replication fork movement using two-dimensional gel electrophoresis showed that the deletion of the DS reduced the initiation events to an undetectable level within the oriP region so that this segment was replicated exclusively by forks entering the region from either direction. A significant slowing or stalling of replication forks that occurs normally at the approximate position of the DS was also eliminated by deletion of the DS. The results confirm the DS as both a replication origin and a place where replication forks pause. Since the replication function of oriP is dispensable at least in certain cell lines, the essential role of EBNA-1 for infection of these cell lines is likely to be that of stabilizing the EBV chromosome by associating with the 30-bp repeats of oriP. The results also imply that in established cell lines, the EBV chromosome can be efficiently replicated entirely from origins that are activated by cellular factors. Presumably, initiation of replication at the DS, mediated by EBNA-1, is important for the natural life cycle of EBV, perhaps in establishing latent infections of normal B cells.     

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.     

The replicator of the Epstein-Barr virus latent cycle origin of DNA replication, oriP, is composed of multiple functional elements

Replication of the Epstein-Barr virus genome initiates at one of several sites in latently infected, dividing cells. One of these replication origins is close to the viral DNA maintenance element, and, together, this replication origin and the maintenance element are referred to as oriP. The replicator of oriP contains four binding sites for Epstein-Barr virus nuclear antigen 1 (EBNA-1), the sole viral protein required for the replication and maintenance of oriP plasmids. We showed previously that these EBNA-1 sites function in pairs and that mutational inactivation of one pair does not eliminate replicator function. In this study we characterized the contribution of each EBNA-1 site within the replicator and flanking sequences through the use of an internally controlled replication assay. We present evidence that shows that all four EBNA-1 sites are required for an oriP plasmid to be replicated in every cell cycle. Results from these experiments also show that the paired EBNA-1 binding sites are not functionally equivalent and that the low affinity of sites 2 and 3 compared to that of sites 1 and 4 is not essential for replicator function. Our results suggest that a host cell protein(s) binds sequences flanking the EBNA-1 sites and that interactions between EBNA-1 and this protein(s) are critical for replicator function. Finally, we present evidence that shows that the minimal replicator of oriP consists of EBNA-1 sites 3 and 4 and two copies of a 14-bp repeat that is present in inverse orientation flanking these EBNA-1 sites. EBNA-1 sites 1 and 2, together with an element(s) within nucleotides 9138 to 9516, are ancillary elements required for full replicator activity.     

Sequence requirements of the Epstein-Barr virus latent origin of DNA replication.

The Epstein-Barr virus (EBV) latent origin of DNA replication (oriP) is composed of two elements that contain binding sites for the sole viral gene product required for latent cycle replication, EBNA-1. One of these elements, region I, functions as an EBNA-1-dependent enhancer for RNA polymerase II-transcribed genes, may play a role in plasmid segregation, and is required for origin function in B cells latently infected with EBV. The second element, region II, contains or is very near the site of initiation of DNA replication. A genetic approach was taken to determine the contribution of the EBNA-1 binding sites in oriP to origin function. Although region I is required for the transient replication of plasmids bearing region II in EBV-infected B cells, a plasmid lacking region I but containing region II, was observed to replicate transiently in both D98/Raji and HeLa cells expressing EBNA-1. Thus, binding of EBNA-1 to region I is not absolutely required for the molecular events that lead to initiation of DNA replication at region II. Site-directed mutagenesis of the four EBNA-1-binding sites in region II, individually and in various combinations, demonstrated that only two EBNA-1-binding sites are required for region II function. The results obtained with these mutants, together with the analysis of the replicative ability of plasmids containing insertions between EBNA-1-binding sites, suggested that the spatial relationship of the two sites is critical. Mutants that contain only two EBNA-1-binding sites separated by 26 to 31 bp in region II were not maintained as plasmids over many cell generations and were greatly reduced in their ability to replicate transiently in D98/Raji cells. The EBNA-1-induced bending or untwisting of the DNA in EBNA-1-binding sites 1 and 4 in region II did not, however, demonstrate this spatial constraint. It may be concluded from these results that specific protein-protein interactions between EBNA-1 and/or between EBNA-1 and a cellular protein(s) are required for origin function.     

Efficient Replication of Epstein-Barr Virus-Derived Plasmids Requires Tethering by EBNA1 to Host Chromosomes

The EBNA1 protein of Epstein-Barr virus enables plasmids carrying oriP both to duplicate and to segregate efficiently in proliferating cells. EBNA1 recruits the origin recognition complex (ORC) to establish a replication origin at one element of oriP, DS (dyad symmetry); at another element, FR (family of repeats), EBNA1 binds to an array of sites from which it tethers plasmids to host chromosomes for mitotic stability. We report experiments leading to the conclusion that tethering by EBNA1 to host chromosomes is also needed within interphase nuclei in order for plasmids to be replicated efficiently from oriP. The DNA-binding domain of EBNA1, which lacks chromosome-binding ability, was found to support weak, DS-specific replication in HEK293 cells after transient transfection, being 17% as active as wild-type EBNA1. The low efficiency of replication was not due to the failure of the DNA-binding domain to retain plasmids within nuclei, because plasmids were recovered in similar amounts and entirely from the nuclear fraction of these transiently transfected cells. A derivative of EBNA1 with its chromosome-tethering domains replaced by a 22-amino-acid nucleosome-binding domain was fully active in supporting oriP functions. The implication is that EBNA1''s DNA-binding domain is able to recruit ORC to DS, but either this step or subsequent replication is only efficient if the plasmid is tethered to a host chromosome. Finally, with some cell lines, DS can hardly support even transient plasmid replication without FR. A loss of plasmids lacking FR from nuclei cannot account for this requirement, suggesting that the stronger tethering to chromosomes by FR is needed for plasmid replication within the nuclei of such cells.     

Coupling of mitotic chromosome tethering and replication competence in epstein-barr virus-based plasmids

The Epstein-Barr virus (EBV) replicates once per cell cycle and segregates with high efficiency yet does not encode the enzymes needed for DNA replication or the proteins required to contact mitotic spindles. The virus-encoded EBNA-1 (EBV nuclear antigen 1) and latent replication origin (oriP) are required for both replication and segregation. We developed a sensitive and specific fluorescent labeling strategy to analyze the interactions of both EBNA-1 with viral episomes and viral episomes with host chromosomes. This enabled investigation of the hypothesis that replication and chromosome tethering are linked through the EBNA-1 protein. We show that deleting EBNA-1 or oriP disrupts mitotic chromosome tethering but removing the dyad symmetry element of oriP does not. Microscopic and biochemical approaches demonstrated that an EBNA-1 mutant lacking residues 16 to 372 bound to oriP plasmids but did not support their mitotic chromosome association and that the mutant lost the ability of wild-type EBNA-1 to associate with interphase chromatin. Importantly, the transient-replication abilities of various mutant forms of EBV plasmids, including the mutant form with the EBNA-1 internal deletion, correlated directly with their chromosome-tethering abilities. These data lead us to propose that EBNA-1 recruits oriP-containing plasmids into chromatin subdomains in interphase nuclei to both engage the host replication machinery and enable the plasmids to adhere to host chromosomes to increase their segregation efficiency.     

Prolonged gene expression in primary porcine pancreatic cells using an Epstein-Barr virus-based episomal vector

Epstein-Barr virus (EBV)-based plasmids containing the origin of replication (oriP) and EBV nuclear antigen 1 (EBNA-1) are well known for the stable episomal maintenance in human cells. In order to clarify whether an EBV-based plasmid can be maintained stably in the porcine pancreatic cells which are the primary candidate sources of islet xenotransplantation, we constructed pEBVGFP encoding the green fluorescent protein (GFP). Monolayer culture of the porcine neonatal pancreatic cells was lipofected with pEBVGFP or pGFP which was derived from pEBVGFP by deleting out oriP and EBNA-1. pEBVGFP significantly prolonged GFP expression not only in human cell lines but also in the primary porcine pancreatic cells compared with pGFP. Interestingly, the duct cells that are believed as the pancreatic precursor cells were preferentially transfected and conveniently enriched among the mixed primary cell populations using a hygromycin B selection. To our knowledge, this is the first report suggesting the potential application of an EBV-based plasmid for the extended gene expression in the primary porcine pancreatic duct cells.     

Epstein-Barr virus (EBV) nuclear antigen 1 colocalizes with cellular replication foci in the absence of EBV plasmids

Epstein-Barr virus (EBV) EBNA-1 is the only EBV-encoded protein that is essential for the once-per-cell-cycle replication and maintenance of EBV plasmids in latently infected cells. EBNA-1 binds to the oriP region of latent EBV plasmids and cellular metaphase chromosomes. In the absence of oriP-containing plasmids, EBNA-1 was highly colocalized with cellular DNA replication foci that were identified by immunostaining S-phase cells for proliferating cell nuclear antigen and replication protein A (RP-A) in combination with DNA short pulse-labeling. For the association of EBNA-1 with the cellular replication focus areas, the EBNA-1 regions of amino acids (aa) 8 to 94 and/or aa 315 to 410, but not the RP-A-interacting carboxy-terminal region, were necessary. These results suggest a new aspect of latent virus-cell interactions.     

Epstein-Barr virus-derived plasmids replicate only once per cell cycle and are not amplified after entry into cells.

Some possible ways in which replication of plasmids containing the Epstein-Barr virus (EBV) plasmid maintenance origin, oriP, might be controlled were investigated. Virtually all plasmid molecules were found to replicate no more than once per cell cycle, whether replication was observed after stable introduction of the plasmids into cells by drug selection or during the first few cell divisions after introducing the DNA into cells. The presence in the cells of excess amounts of EBNA1, the only viral protein needed for oriP function, did not increase the number of oriP-replicated plasmids maintained by cells under selection. In the cell lines studied, EBNA1 and oriP seem to lack the capacity to override the cellular controls that limit DNA replication to one initiation event per DNA molecule per S phase. The multicopy status of EBV-derived, selectable plasmids appears to result from the initial uptake by cells of large numbers of plasmid molecules, the efficient maintenance of these plasmids, and the pressure of genetic selection against plasmid loss. Other unknown controls must be responsible for the amplification of EBV genomes soon after latent infection of cells.     

The amino terminus of Epstein-Barr Virus (EBV) nuclear antigen 1 contains AT hooks that facilitate the replication and partitioning of latent EBV genomes by tethering them to cellular chromosomes

During latency, Epstein-Barr virus (EBV) is stably maintained as a circular plasmid that is replicated once per cell cycle and partitioned at mitosis. Both these processes require a single viral protein, EBV nuclear antigen 1 (EBNA1), which binds two clusters of cognate binding sites within the latent viral origin, oriP. EBNA1 is known to associate with cellular metaphase chromosomes through chromosome-binding domains within its amino terminus, an association that we have determined to be required not only for the partitioning of oriP plasmids but also for their replication. One of the chromosome-binding domains of EBNA1 associates with a cellular nucleolar protein, EBP2, and it has been proposed that this interaction underlies that ability of EBNA1 to bind metaphase chromosomes. Here we demonstrate that EBNA1's chromosome-binding domains are AT hooks, a DNA-binding motif found in a family of proteins that bind the scaffold-associated regions on metaphase chromosomes. Further, we demonstrate that the ability of EBNA1 to stably replicate and partition oriP plasmids correlates with its AT hook activity and not its association with EBP2. Finally, we examine the contributions of EBP2 toward the ability of EBNA1 to associate with metaphase chromosomes in human cells, as well as support the replication and partitioning of oriP plasmids in human cells. Our results indicate that it is unlikely that EBP2 directly mediates these activities of EBNA1 in human cells.     

Human origin recognition complex binds to the region of the latent origin of DNA replication of Epstein-Barr virus

Epstein-Barr virus (EBV) replicates in its latent phase once per cell cycle in proliferating B cells. The latent origin of DNA replication, oriP, supports replication and stable maintenance of the EBV genome. OriP comprises two essential elements: the dyad symmetry (DS) and the family of repeats (FR), both containing clusters of binding sites for the transactivator EBNA1. The DS element appears to be the functional replicator. It is not yet understood how oriP-dependent replication is integrated into the cell cycle and how EBNA1 acts at the molecular level. Using chromatin immunoprecipitation experiments, we show that the human origin recognition complex (hsORC) binds at or near the DS element. The association of hsORC with oriP depends on the DS element. Deletion of this element not only abolishes hsORC binding but also reduces replication initiation at oriP to background level. Co-immunoprecipitation experiments indicate that EBNA1 is associated with hsORC in vivo. These results indicate that oriP might use the same cellular initiation factors that regulate chromosomal replication, and that EBNA1 may be involved in recruiting hsORC to oriP.     

Genetic evidence that EBNA-1 is needed for efficient, stable latent infection by Epstein-Barr virus

Replication and maintenance of the 170-kb circular chromosome of Epstein-Barr virus (EBV) during latent infection are generally believed to depend upon a single viral gene product, the nuclear protein EBNA-1. EBNA-1 binds to two clusters of sites at oriP, an 1, 800-bp sequence on the EBV genome which can support replication and maintenance of artificial plasmids introduced into cell lines that contain EBNA-1. To investigate the importance of EBNA-1 to latent infection by EBV, we introduced a frameshift mutation into the EBNA-1 gene of EBV by recombination along with a flanking selectable marker. EBV genomes carrying the frameshift mutation could be isolated readily after superinfecting EBV-positive cell lines, but not if recombinant virus was used to infect EBV-negative B-cell lines or to immortalize peripheral blood B cells. EBV mutants lacking almost all of internal repeat 3, which encode a repetitive glycine and alanine domain of EBNA-1, were generated in the same way and found to immortalize B cells normally. An EBNA-1-deficient mutant of EBV was isolated and found to be incapable of establishing a latent infection of the cell line BL30 at a detectable frequency, indicating that the mutant was less than 1% as efficient as an isogenic, EBNA-1-positive strain in this assay. The data indicate that EBNA-1 is required for efficient and stable latent infection by EBV under the conditions tested. Evidence from other studies now indicates that autonomous maintenance of the EBV chromosome during latent infection does not depend on the replication initiation function of oriP. It is therefore likely that the viral chromosome maintenance (segregation) function of oriP and EBNA-1 is what is required.