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.     

The Epstein-Barr virus origin of plasmid replication, oriP, contains both the initiation and termination sites of DNA replication

Epstein-Barr virus (EBV) oriP contains two components, a dyad symmetry element and a direct repeat element, that, in the presence of EBV nuclear antigen 1, are necessary and sufficient for plasmid replication. We have examined the replicative forms generated by EBV oriP using 2D gel electrophoresis. The patterns obtained from an oriP plasmid in a transfected cell line indicate that the site of initiation of DNA replication is at or very near the dyad symmetry element, while the direct repeats contain a replication fork barrier and the termination site. Thus, replication from oriP proceeds in a predominantly undirectional manner. The patterns obtained from cells immortalized by EBV suggest that replication from oriP proceeds similarly in the viral genome.     

Constitutive binding of EBNA1 protein to the Epstein-Barr virus replication origin, oriP, with distortion of DNA structure during latent infection.

Replication of the circular, 170 kb genome of Epstein-Barr virus (EBV) during latent infection is performed by the cellular replication machinery under cell-cycle control. A single viral protein, EBNA1, directs the cellular replication apparatus to initiate replication within the genetically defined replication origin, oriP, at a cluster of four EBNA1 binding sites, referred to here as the physical origin of bidirectional replication, or OBR. A second cluster of EBNA1 binding sites within oriP, the 30 bp repeats, serves an essential role as a replication enhancer and also provides a distinct episome maintenance function that is unrelated to replication. We examined the functional elements of oriP for binding by EBNA1 and possibly other proteins in proliferating Raji cells by generating in vivo footprints using two reagents, dimethylsulfate (DMS) and KMnO4. We also employed deoxyribonuclease I (DNase I) with permeabilized cells. The in vivo and permeabilized cell footprints at the EBNA1 binding sites, particularly those obtained using DMS, gave strong evidence that all of these sites are bound by EBNA1 in asynchronously dividing cells. No consistent evidence was found to suggest binding by other proteins at any other sites within the functional regions of oriP. Thymines at symmetrical positions of the OBR within oriP were oxidized when cells were treated with permanganate, suggestive of bends or other distortions of DNA structure at these positions; binding of EBNA1 in vitro to total DNA from Raji cells induced reactivity to permanganate at identical positions. The simplest interpretation of the results, which were obtained using asynchronously dividing cells, is that EBNA1 binds to its sites at oriP and holds the OBR in a distorted conformation throughout most of the cell cycle, implying that replication is initiated by a cellular mechanism and is not limited by an availability of EBNA1 for binding to oriP.     

Interaction of the lymphocyte-derived Epstein-Barr virus nuclear antigen EBNA-1 with its DNA-binding sites.

The Epstein-Barr virus (EBV) nuclear antigen EBNA-1 plays an integral role in the maintenance of latency in EBV-infected B lymphocytes. EBNA-1 binds to sequences within the plasmid origin of replication (oriP). It is essential for the replication of the latent episomal form of EBV DNA and may also regulate the expression of the EBNA group of latency gene products. We have used sequence-specific DNA-binding assays to purify EBNA-1 away from nonspecific DNA-binding proteins in a B-lymphocyte cell extract. The availability of this eucaryotic protein has allowed an examination of the interaction of EBNA-1 with its specific DNA-binding sites and an evaluation of possible roles for the different binding loci within the EBV genome. DNA filter binding assays and DNase I footprinting experiments showed that the intact Raji EBNA-1 protein recognized the two binding site loci in oriP and the BamHI-Q locus and no other sites in the EBV genome. Competition filter binding experiments with monomer and multimer region I consensus binding sites indicated that cooperative interactions between binding sites have relatively little impact on EBNA-1 binding to region I. An analysis of the binding parameters of the Raji EBNA-1 to the three naturally occurring binding loci revealed that the affinity of EBNA-1 for the three loci differed. The affinity for the sites in region I of oriP was greater than the affinity for the dyad symmetry sites (region II) of oriP, while the physically distant region III locus showed the lowest affinity. This arrangement may provide a mechanism whereby EBNA-1 can lowest affinity. This arrangement may provide a mechanism whereby EBNA-1 can mediate differing regulatory functions through differential binding to its recognition sequence.     

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.     

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.     

Identification of an origin of bidirectional DNA replication in mammalian chromosomes

Mechanistically, an origin of bidirectional DNA replication (OBR) can be defined by the transition from discontinuous to continuous DNA synthesis that must occur on each template strand at the site where replication forks originate. This results from synthesis of Okazaki fragments predominantly on the retrograde arms of forks. We have identified these transitions at a specific site within a 0.45 kb sequence approximately 17 kb downstream from the 3' end of the dihydrofolate reductase gene in Chinese hamster ovary chromosomes. At least 80% of the replication forks in a 27 kb region emanated from this OBR. Thus, initiation of DNA replication in mammalian chromosomes uses the same replication fork mechanism previously described in a variety of prokaryotic and eukaryotic genomes, suggesting that mammalian chromosomes also utilize specific cis-acting sequences as origins of DNA replication.     

The dyad symmetry element of Epstein-Barr virus is a dominant but dispensable replication origin

OriP, the latent origin of Epstein-Barr virus (EBV), consists of two essential elements: the dyad symmetry (DS) and the family of repeats (FR). The function of these elements has been predominantly analyzed in plasmids transfected into transformed cells. Here, we examined the molecular functions of DS in its native genomic context and at an ectopic position in the mini-EBV episome. Mini-EBV plasmids contain 41% of the EBV genome including all information required for the proliferation of human B cells. Both FR and DS function independently of their genomic context. We show that DS is the most active origin of replication present in the mini-EBV genome regardless of its location, and it is characterized by the binding of the origin recognition complex (ORC) allowing subsequent replication initiation. Surprisingly, the integrity of oriP is not required for the formation of the pre-replicative complex (pre-RC) at or near DS. In addition we show that initiation events occurring at sites other than the DS are also limited to once per cell cycle and that they are ORC-dependent. The deletion of DS increases initiation from alternative origins, which are normally used very infrequently in the mini-EBV genome. The sequence-independent distribution of ORC-binding, pre-RC-assembly, and initiation patterns indicates that a large number of silent origins are present in the mini-EBV genome. We conclude that, in mini-EBV genomes lacking the DS element, the absence of a strong ORC binding site results in an increase of ORC binding at dispersed sites.     

Replication from oriP of Epstein-Barr virus requires human ORC and is inhibited by geminin

A hypomorphic mutation made in the ORC2 gene of a human cancer cell line through homologous recombination decreased Orc2 protein levels by 90%. The G1 phase of the cell cycle was prolonged, but there was no effect on the utilization of either the c-Myc or beta-globin cellular origins of replication. Cells carrying this mutation failed to support the replication of a plasmid bearing the oriP replicator of Epstein Barr virus (EBV), and this defect was rescued by reintroduction of Orc2. Orc2 specifically associates with oriP in cells, most likely through its interaction with EBNA1. Geminin, an inhibitor of the mammalian replication initiation complex, inhibits replication from oriP. Therefore, ORC and the human replication initiation apparatus is required for replication from a viral origin of replication.     

Single-stranded structures are present within plasmids containing the Epstein-Barr virus latent origin of replication.

The Epstein-Barr virus (EBV) latent origin of plasmid replication (oriP) contains two essential regions, a family of repeats with 20 imperfect copies of a 30-bp sequence and a dyad symmetry element with four similar 30-bp repeats. Each of the repeats has an internal palindromic sequence and can bind EBNA 1, a protein that together with oriP constitutes the only viral element necessary for EBV maintenance and replication. Using single-strand-specific nucleases, we have probed plasmids containing oriP-derived sequences for the presence of secondary structural elements. Multiple single-stranded structures were detected within the oriP region. Of the two essential elements of oriP, the family of repeats seemed to extrude these structures at a much higher frequency than did sequences within the dyad symmetry region. Though negative supercoiling was found to stabilize the single-stranded structures, they showed significant stability even after linearization of the oriP plasmids. Two major single-stranded structures detected involved approximately 12 bp of DNA. These loci could be transiently unwound regions that form because of negative supercoiling and the high A + T content of this region of DNA, or they could be cruciform structures extruded within the palindromic sequences of oriP that may be important sites for protein-DNA interactions in the EBV oriP.     

Identification of a herpesvirus Saimiri cis-acting DNA fragment that permits stable replication of episomes in transformed T cells.

Herpesvirus saimiri is a lymphotropic herpesvirus capable of immortalizing and transforming T cells both in vitro and in vivo. Immortalized and transformed T cells harbor several copies of the viral genome as a persisting genome. The mapping of the cis-acting genetic cis-acting segment (oriP) required for viral episomal maintenance is reported here. Viral DNA fragments that potentially contain oriP were cloned into a plasmid that contains the hygromycin resistance gene. After several round of subcloning followed by transfection, oriP was mapped to a 1.955-kb viral segment. This viral fragment permits stable plasmid replication without deletion or rearrangement as well as episomal maintenance without integration or recombination. The function of oriP depends on a trans-acting factor(s) encoded by the viral genome. The 1.955-kb viral segment includes a dyad symmetry region located between two small nuclear RNA genes and is located upstream of the dihydrofolate reductase gene homolog. Therefore, this oriP contains novel elements distinct from those of other DNA viruses.     

真核细胞染色体DNA复制起始及复制叉稳定性维持的机制

在真核生物中,DNA复制在染色体上特定的多位点起始．当细胞处在晚M及G1期,多个复制起始蛋白依次结合到DNA复制源,组装形成复制前复合体．pre．RC在Gl-S的转折期得到激活,随后,多个直接参与DNA复制又形成的蛋白结合到DNA复制源,启动DNA的复制,形成两个双向的DNA复制又．在染色体上,移动的DNA复制又经常会碰到复制障碍（二级DNA结构、一些蛋白的结合位点、损伤的碱基等）而暂停下来,此时,需要细胞周期检验点的调控来稳定复制叉,否则,会导致复制又垮塌及基因组不稳定．本文就真核细胞染色体DNA复制起始的机制,以及复制又稳定性的维持机制进行简要综述．     

rDNA enhancer affects replication initiation and mitotic recombination: Fob1 mediates nucleolytic processing independently of replication

To investigate the influence of the ribosomal DNA enhancer on initiation of replication and recombination at the ribosomal array, we used yeast S. cerevisiae strains with adjacent, tagged rRNA genes. We found that the enhancer is an absolute requirement for replication fork barrier function, while it only modulates initiation of replication. Moreover, the formation of monomeric extrachromosomal ribosomal circles depends on this element. Our data indicate that DNA double-strand breaks occur at specific sites in the parental leading arm of replication forks stalled at the replication fork barrier. Additionally, nicks upstream of the replication fork barrier were visualized by nucleotide-resolution mapping. They coincide with essential sequences of the mitotic hyperrecombination site HOT1, which previously has been determined at ectopic sites. Interestingly, these nicks are strictly dependent on the replication fork blocking-protein (Fob1), but are replication independent, suggesting that intrachromosomal ribosomal DNA recombination may occur outside of S phase.