Mechanisms of infection with Epstein-Barr virus. I. Viral DNA replication and formation of noninfectious virus particles in superinfected Raji cells

The Epstein-Barr virus alkaline exonuclease BGLF5 serves pleiotropic functions in virus replication

The Epstein-Barr virus (EBV) alkaline exonuclease BGLF5 has previously been recognized to contribute to immune evasion by downregulating production of HLA molecules during virus replication. We have constructed a BGLF5-null virus mutant to determine BGLF5's functions during EBV viral replication. Quantification of virus production in permissive 293 cells carrying a DeltaBGLF5 genome identified a 17- to 21-fold reduction relative to complemented or wild-type controls. Detailed monitoring of DeltaBGLF5 replication evidenced an impaired virus nucleocapsid maturation, a reduced primary egress and a 1.4-fold reduction in total viral DNA synthesis. DeltaBGLF5 single-unit-length viral genomes were not only less abundant but also migrated faster than expected in gel electrophoresis. We concluded that BGLF5 pertained both to the generation and to the processing of viral linear genomes. DeltaBGLF5 phenotypic traits were reminiscent of those previously identified in a mutant devoid of UL12, BGLF5's homolog in herpes simplex virus type 1, and indeed UL12 was found to partially complement the DeltaBGLF5 phenotype. However, BGLF5-specific functions could also be identified; the nuclear membrane of replicating cells displayed images of reduplication and complex folding that could be completely corrected by BGLF5 but not UL12. Similar nuclear abnormalities were previously observed in cells transfected with BFLF2 and BFRF1, two viral proteins crucial for EBV nuclear egress. Interestingly, DeltaBGLF5 cells produced more BFLF2 than wild-type or complemented counterparts. The present study provides an overview of BGLF5's functions that will guide future molecular studies. We anticipate that the 293/DeltaBGLF5 cell line will be instrumental in such developments.

Mono/oligoclonal pattern of Kaposi Sarcoma-associated herpesvirus (KSHV/HHV-8) episomes in primary effusion lymphoma cells

Primary effusion lymphoma (PEL) is a rare lymphoma of B-cell origin, developed in serous cavities. PEL tumor cells are latently infected with Kaposi sarcoma-associated herpesvirus (KSHV) and in most cases co-infected with Epstein-Barr virus (EBV). In 15 primary PEL tumors including 10 EBV-positive cases, we analyzed the fused terminal repeat (TR) regions of KSHV episomes using pulsed-field gel electrophoresis and Southern blot. On the same genomic DNA samples, the cellular clonality was assessed by Southern blot and PCR detection of monoclonal immunoglobulin heavy chain (IGH) VDJ gene rearrangements, associated in the EBV-infected cases, with Southern blot analysis of the fused termini of EBV episomes. Monoclonal IGH gene rearrangements were detected in 13 tumors using Southern blot, in 11 cases using PCR, and in all cases considering both methods. EBV infection was monoclonal in all EBV-positive cases. However, only 5 PEL tumors were found to be monoclonally infected with KSHV. In the 10 other cases, we found a biclonal (2 bands; n = 4) or an oligoclonal pattern (3-6 bands; n = 6) of KSHV episomes. We hypothesized that the apparent discrepancy between viral and cellular clonalities in PEL might be due to several phenomena including complex mechanisms of genomic recircularization, insertion of duplicated sequences into the TR region and simultaneous infection of tumor cells with defective KSHV variants. KSHV infection of contaminating nontumoral cells, superinfection from lytically infected cells or viral integration events might also explain the oligoclonal pattern of KSHV infection. Several of these mechanisms, not mutually exclusive, might coexist in a single tumor.

Epstein-Barr virus: the hematologic and oncologic consequences of virus-host interaction

Varicella-zoster virus (VZV) and Epstein-Barr virus (EBV) are two of the human herpesviruses. The others include herpes simplex virus (HSV) type 1, HSV type 2, and cytomegalovirus (CMV). In a series of two articles, we review the clinical diseases caused by VZV and EBV infections; we pay particular attention to the manifestations of these two viral infections in immunosuppressed and immunocompromised patients. In addition to the clinical reviews, each of the two articles begins with a brief discussion of the molecular aspects of VZV and EBV, respectively; this introduction describes features of the genome and immunogenic viral proteins which have clinical relevance. A model for pathogenesis is included. The first review concerns VZV infections. Recent data about the DNA sequence of the entire VZV genome are included, as well as a review of the VZV glycoproteins. Primary VZV infection (chickenpox) and VZV reactivation (zoster) are described in detail in both healthy individuals and people with cancer. The decade-long VZV vaccine trials in children with leukemia receive special emphasis because they have engendered considerable interest and debate. The second review (published here) covers EBV infections. This virus has been implicated in the causation of a wide variety of human hematological and oncological disorders, besides classical infectious mononucleosis. In particular, Burkitt's lymphoma, nasopharyngeal carcinoma, and lymphoproliferative disorders are strongly associated with EBV infection of the transformed cells. In addition, immunologically mediated cytopenias occasionally follow EBV infection. Finally, treatment regimens with antiviral chemotherapy and other agents are discussed for both VZV and EBV infections.

A virion-like particle (VLP) released from an Epstein-Barr virus-producing cell sub-line of P3HR-1: identification of a specific cellular DNA contained within VLPs

A virion-like particle (VLP) was isolated from the culture fluid of P3HR-I cells. VLPs were separable from the enveloped Epstein-Barr virus (EBV) through rate-velocity sedimentation by virtue of their greater density. VLPs comprised electron-dense nucleoid material and the surrounding round or oval envelope which ranged from 100 to 150 nm in diameter. The polypeptide constitution of VLPs was very similar to that of enveloped EBV by SDS-polyacrylamide gel electrophoresis. VLPs contained reasonably specific cellular DNA (VLP DNA) with a sedimentation coefficient of 48S, which was cleaved into 5, 8, and at least 30 specific DNA fragments by digestion with BamHI, SalI, and EcoRI, respectively. Blot hybridization data suggested a limited heterogeneous genomic organization of VLP DNA and the presence of a VLP DNA-related molecule(s) in human cord lymphocytes.

Mapping of genes in BamHI fragment M of Epstein-Barr virus DNA that may determine the fate of viral infection

We used nuclease digestion to map RNA transcripts encoded in the BamHI M fragment of the Epstein-Barr virus (EBV) genome (strain B95-8). Of the five RNAs, three are rightwardly transcribed, have different cap sites but common 3' termini, and are unspliced. The two remaining RNAs are leftwardly transcribed and are 5' and 3' coterminal. One of these transcripts is spliced, resulting in the removal of a small intron from the 5' region of this RNA. We have previously published data which indicated that the BamHI M region is the first actively transcribed region of the viral genome during the replicative cycle, suggesting that one or more genes in this region is important in the initiation of EBV replication. We have now mapped two large EcoRI restriction fragments which span approximately 75% of the P3HR-1 defective genome and which contain DNA from the BamHI M region of the standard genome. The data indicate that only the coding and 5' flanking sequences for the leftwardly transcribed RNAs are intact within the defective genome. Fewer than 500 bases coding for the 3'-most regions of the rightwardly transcribed RNAs are intact, and it is unlikely that these encode functional native polypeptides. Therefore, it seems that transcriptional activation of the BamHI M-region genes is not mediated directly by the rearrangement of M genes in defective P3HR-1 EBV.

Induction of a deoxyuridine triphosphate nucleotidohydrolase activity in Epstein-Barr virus-infected cells

Superinfection of Raji cells with Epstein-Barr virus (EBV) or chemical induction of HR-1 cells with 12-O-tetradecanoyl-phorbol-13-acetate (TPA) results in the induction of a deoxyuridine triphosphate nucleotidohydrolase (dUTPase) which is not observed in mock-treated cells or TPA-treated EBV genome-negative BJAB cells. The EBV-induced dUTPase could be distinguished from the host dUTPase based upon differences in their migration in polyacrylamide gels and sensitivity to the 5-mercurithioguanosine derivitive of dUTP. The expression of the EBV-specified dUTPase is prevented by phosphonoacetic acid indicating that its expression is dependent upon EBV-DNA replication.

Identification of Epstein-Barr virus genes expressed during the early phase of virus replication and during lymphocyte immortalization

Transcription of the Epstein-Barr virus (EBV) genome in Raji cells superinfected with P3HR-1 EBV in the presence of cycloheximide was compared to transcription in human lymphocytes infected with transforming EBV (B95-8). This was done to identify regions of the EBV genome which contain genes that may mediate initiation of virus replication. Hybridization of 32P-labeled cDNA to cloned fragments of EBV DNA (dot blot hybridization) was employed to identify transcriptionally active regions of the viral genome in these cells. DNA in the BamHI A, F, H, and M restriction fragments was found to encode poly(A) RNA during the early phase of EBV replication. In the absence of cycloheximide the earliest detectable transcripts were transcribed from the BamHI M region. The most transcriptionally active region of the EBV genome in lymphocytes following infection with EBV (B95-8) was the BamHI W-Y-H-F region and, to a lesser extent, the K region. Transcription of the BamHI M region was not detected in these cells. The data suggest that expression of a gene or genes located in the BamHI M region of the EBV genome is an important event in the initiation of EBV replication, whereas expression of the genes in the BamHI W-Y-H-F and K regions may be important in the establishment of latency and cellular immortalization.

Epstein-Barr virus (P3HR-1) defective DNA codes for components of both the early antigen and viral capsid antigen complexes

A set of lambda phages containing overlapping fragments of Epstein-Barr virus (EBV) defective DNA has been cloned from P3HR-1-superinfected Raji cells. Mapping data obtained using these cloned DNA fragments confirmed the structure of P3HR-1 defective DNA previously deduced directly from virion DNA (M.-S. Cho, G. W. Bornkamm, and H. zur Hausen, 1984, J. Virol., in press). The ability of the cloned defective DNA fragments to induce EBV antigens in transfected baby hamster kidney (BHK) cells was tested using indirect immunofluorescence assays. Up to 5% of those cells receiving a defective DNA fragment BamHI-W'C' transiently expressed a de novo nuclear antigen which was identified as being a component of the EAD complex by its reactivity with characterized EBV-positive human sera. A 20-kb clone of P3HR-1 defective DNA (EcoRI-C1) was found to induce the synthesis of a component of the VCA complex. One percent of cells transfected with this clone showed cytoplasmic fluorescence when tested with either VCA+ human sera or EBV anti-VCA monoclonal antibody. Subcloning of the EcoRI-C1 fragment localized the VCA gene to a 4.1-kb segment which maps within the BamHI-A fragment of the standard genome. This segment contains a single large open reading frame of 2.6 kb (B. Barrell, A. Bankier, R. Baer, P. Biggin, P. Deininger, P. Farrell, T. Gibson, G. Hatfull, G. Hudson, S. Stachwell, and C. Sequin, 1984, Nature (London), in press). None of the defective DNA clones were capable of inducing EBV-specific nuclear antigens (EBNAs) which is consistent with the absence of the known EBNA coding regions from the defective genome.

Structure of defective DNA molecules in Epstein-Barr virus preparations from P3HR-1 cells

Epstein-Barr virus (EBV), isolated from P3HR-1 cells, induces early antigen and viral capsid antigen upon infection of human B-lymphoblasts. The strong early antigen- and viral capsid antigen-inducing activity is only observed in P3HR-1 virus preparations harboring particles with defective genomes, suggesting that this biological activity is directly associated with the defective DNA population. After infection of EBV genome-carrying Raji or EBV genome-negative BJAB cells, defective genomes of P3HR-1 EBV DNA are replicated in excess, depending on the multiplicity of infecting EBV particles. Hybridization of the DNA from such infected cells with 32P-labeled EBV DNA after HindIII cleavage reveals six hypermolar fragments. Mapping of these fragments shows that they form one defective genome unit containing four nonadjacent regions (alpha, beta, gamma, and delta) of the nondefective P3HR-1 EBV DNA. Two of the segments (alpha and beta) contain ca. 17 and 13 megadaltons, respectively, from the terminal regions of the P3HR-1 genome, whereas the two smaller segments (gamma and delta) contain ca. 3.7 and 3.0 megadaltons, respectively, originating from the central portion of the genome. In the defective molecule, the regions gamma and delta are present in the opposite orientation compared with nondefective P3HR-1 EBV DNA. Tandem concatemers are formed by fusion of the alpha and beta regions. Our model suggests that tandem concatemers of three defective genome units can be packaged into virions in P3HR-1 cells.

Multiplicity-dependent induction of viral capsid antigen in Raji cells superinfected with Epstein-Barr virus

A quantitative analysis of Epstein-Barr virus (EBV)-induced early antigen (EA) and viral capsid antigen (VCA) syntheses was carried out in Raji cells superinfected with purified, concentrated P3HR-1 EBV. When the cells were exposed to the virus and assessed by immunofluorescence and immunoprecipitation, EA induction occurred significantly (17%) but not VCA (less than 1%), at a low-input multiplicity of infection (MOI) of 10 EBV DNA copies/cell. In contrast, at a high MOI of 500 EBV DNA copies/cell, the majority of cells were positive for both EA (82%) and VCA (61%). The latter VCA synthesis was accompanied by the replication of EBV DNA. Kinetic studies showed that EA induction was directly proportional to the dilution of the infecting virus, while VCA was made following three-hit kinetics. The implications of these results are discussed in relation to the heterogeneous nature of P3HR-1 EBV and a possible role of EA in VCA synthesis.

The interaction of non-transforming Epstein-Barr virus (EBV) with cell-associated EBV DNA in superinfected lymphoblastoid cell lines

Two human lymphoblastoid cell lines were established by the transformation of human cord-blood lymphocytes with transforming Epstein-Barr virus (EBV). One cell line (HLB-R1) was established with EBV obtained after the superinfection of Raji cells with HR-1 EBV and the other (HLB-Bl) was established from B95-8 EBV-infected human cord-blood lymphocytes. Both the HLB-R1 and HLB-B1 lines were susceptible to superinfection with HR-1 EBV. We found that EBV DNA was replicated in the superinfected cell lines and that transforming EBV was produced in both the HLB-B1 and HLB-R1 cells. The average titer of transforming EBV obtained in the HR-1 EBV superinfected HLB-B1 and HLB-R1 cell lines was 10(4) transforming units (TU)/ml, whereas the average titers of transforming EBV obtained by the superinfection of Raji cells was 10(1) TU/ml. Epstein-Barr virus capable of inducing early antigen (EA) in superinfected Raji cells (lytic virus) was not detected in any transforming virus preparation. Restriction enzyme digestion patterns of virus DNA isolated from HR-1 and B95-8 cells, as well as from superinfected cells, were compared. The EBV DNA that was replicated in the superinfected HLB-R1 and HLB-B1 cell lines showed a more complex pattern. Our data suggest that recombination between input HR-1 EBV DNA and latent cell-associated EBV DNA occurs. Presumably this recombination results in a change in the biological properties of the newly synthesized virus.

Filamentous structures associated with Epstein-Barr virus-infected cells

After the onset of Epstein-Barr virus DNA and protein synthesis 10 h after superinfection of Raji cells (a cell line containing Epstein-Barr virus DNA but not producing virus), filamentous structures 25 nm in diameter and 0.2 to 1.4 micrometers in length could be detected in the cell cytoplasm by electron microscopy. These structures banded in metrizamide gradients with viral DNA and proteins, but at a density different from that of virions or nucleocapsids. These filaments, enriched in a 155,000-dalton protein similar in size to a major nucleocapsid protein of Epstein-Barr virus, may represent intermediates in viral nucleocapsid assembly.

Epstein-Barr virus polypeptides: identification of early proteins and their synthesis and glycosylation

We have identified at least six early polypeptides induced by Epstein-Barr virus in cells or under conditions which are nonpermissive for Epstein-Barr virus DNA replication ranging in molecular weight from 140,000 to 26,000.

Epstein-Barr virus membrane antigens: characterization, distribution, and strain differences

The Epstein-Barr virus (EBV)-associated membrane antigen polypeptides (350,000, 220,000, 140,000, and 85,000 daltons) are recognized by a rabbit anti-EBV serum and are present on the plasma membranes of producer cell lines, as we demonstrated previously. In this report, we show that these polypeptides are present on intact virus particles. Subcellular fractionation revealed that these antigens are distributed throughout the cell, except for the 85,000-dalton protein, which was poorly represented in the nuclear fraction. In addition, an EBV-associated protein of 160,000 daltons, which comigrates with a major component of the viral capsid, was detected in the cytoplasmic and nuclear fractions. The immunoprecipitation patterns of 13 different EBV isolates were similar, with two exceptions. First, the 350,000- and 220,000-dalton polypeptides from marmoset cell lines had slightly larger molecular sizes than the corresponding polypeptides from human cell lines. Second, B95-8 virus and B95-8-derived human and marmoset cell lines contained little of the 220,000-dalton protein; however, 883L, the human parent line of B95-8, has a normal amount of the 220,000-dalton protein. Thus, the B95-8 strain of EBV appears to be a structurally defective variant. We have not observed any variation in protein patterns associated with different EBV disease states. The 350,000-, 220,000-, and 85,000-dalton polypeptides were shown to be glycoproteins by incorporation of [3H]mannose and [3H]glucosamine and to contain N-asparagine-linked glycosyl groups by their sensitivity to tunicamycin. To simplify future work, the following nomenclature for these EBV-associated polypeptides is suggested: 350,000 (gp350), 220,000 (gp220), 160,000 (p160), 140,000 (p140), and 85,000 (gp85).

Sedimentation characteristics of newly synthesized Epstein-Barr viral DNA in superinfected cells

Replicating Epstein-Barr virus (EBV) DNA molecules isolated from superinfected Raji cells were shown to consist of 80S to 65S and 58S (mature) molecules Pulse-chase experiments showed that radioactive label of DNAS molecules with the larger sedimentation coefficients was partially chased into 58S labeled forms. Formation of large concatemers of viral DNA could not be detected at any time after superinfection. The continuous presence of the 65S viral DNA intermediate throughout the replicative cycle combined with the observed inhibition of EBV DNA synthesis by addition of nontoxic levels of ethidium bromide to the superinfected cell culture led us to propose that EBV replication proceeds via a relaxed circular DNA intermediate.

Epstein-Barr virus polypeptides: effect of inhibition of viral DNA replication on their synthesis

After Epstein-Barr virus superinfection of the human lymphoblastoid cell line Raji, a Burkitt lymphoma-derived line that contains Epstein-Barr virus genomes in an episomal form, at least 40 polypeptides could be resolved by polyacrylamide gel electrophoresis. Eleven of the 40 polypeptides were immunoprecipitable by early antigen+/viral capsid antigen+ antiserum. The polypeptides could be divided into six classes, immediate-early, early, intermediate, late, very late, and persistent, depending upon the time of synthesis. Ten of the 40 polypeptides appeared to preexist before superinfection and persisted despite general cessation of host protein synthesis; none of the persistent proteins was immunoprecipitated by the Epstein-Barr virus antibody-containing serum. When viral DNA replication was blocked by a variety of inhibitors of DNA synthesis, a number of different patterns of polypeptide synthesis could be detected. The synthesis of six polypeptides was blocked by the most virus-specific inhibitors, acyclovir and phosphonoacetic acid. Additionally, in the presence of 1-beta-D-arabinofuranosylcytosine, 1-beta-D-arabinofuranosyladenine, and methotrexate, seven polypeptides showed oversynthesis.

Epstein--Barr virus-induced cell fusion

Serological and molecular biological studies have shown an association between Epstein--Barr virus (EBV) and nasopharyngeal carcinoma. Although it has been shown that the epithelioid tumour cells carry EBV genomes, they are apparently devoid of receptors for EBV (H.W., unpublished observations). Other have suggested that fusion of EBV carrying cells with epithelial cells may be the mode of entry of the virus into cells unable to absorb the virus and that this may be mediated by one of the known syncytium-forming viruses which inhabit the respiratory tract (for example, members of the paramyxovirus group). de Thé and colleagues suggested that intercellular bridges could be seen in NPC tumour material. We have developed a technique which permits the preparation of stable monolayers of viable human lymphoblastoid cell lines. Using this technique we have now demonstrated that EBV can induce fusion between EBV-superinfected lymphoblastoid cells and cells devoid of EBV receptors.

Differential inhibition of Epstein-Barr virus induction by the amino acid analogue, L-canavanine

The effect of an amino acid analogue, L-canavanine, on the synthesis of Epstein-Barr virus (EBV) antigens was investigated in lymphoblastoid cells. The analysis revealed that after infection of BJAB and NC-37 cells with P3HR-I EBV synthesis of early antigen (EA) was not affected by canavanine in concentrations up to 8.4 mM. The synthesis of EBV-determined nuclear antigen (EBNA) and of viral capsid antigen (VCA) was significantly inhibited at concentrations higher than 2.8 mM. Spontaneous induction of EA in P3HR-I cells was not affected by canavanine. On the other hand, EA induction by the tumor promoter TPA resulted in some viral antigen induction depending on the time period of TPA exposure. Pretreatment of the cells overnight with canavanine followed by washing and addition of the tumor promoter did not suppress EA induction by TPA. These data support the concept that EA induction by superinfection follows a different pathway from antigen induction by chemical inducers.

Nucleosomal structure of Epstein-Barr virus DNA in transformed cell lines

Micrococcal nuclease digestion was used to analyze Epstein-Barr virus (EBV) DNA structure in nuclei of transformed cells. Digests of virus-producing (P3HR-1), non-virus-producing (Raji), and superinfected Rajii cell nuclei were fractionated by electrophoresis on agarose gels, transferred to nitrocellulose, and hybridized to 32P-labeled EBV DNA. The viral DNA of Raji nuclei produced a series of bands on electrophoresis whose lengths were integral multiples of a unit size, which was the same as the repeat length of host DNA. Viral DNA in nuclei of P3HR-1 and superinfected Raji cells produced faintly visible bands superimposed on a smear of viral DNA which dominated the hybridization pattern. No differences were detected in the patterns when total DNA digests from Raji, P3HR-1, and an EBV DNA-negative cell line (U-698M) were analyzed by ethidium bromide staining or by hybridization with the use of 32P-labeled lymphoblastoid cell DNA as probe. We conclude that the EBV episomal DNA of Raji cells is folded into nucleosomes, whereas most of the viral DNA of P3HR-1 and superinfected Raji cells is not. This pattern of DNA organization differs signficantly from that in papova group viruses.

Recovery of transforming EBV from non-producer cells after superinfection with non-transforming P3HR-1 EBV

Cells of the Raji and NC37 lines can be induced by chemical inducers, such as BrdUrd and IdUrd, or the tumor-promoter TPA to EA-expression only, but do not reveal any VCA synthesis. After superinfection by nontransforming P3HR-1 EBV, however, a varying percentage of the cell population shows VCA synthesis and releases infectious viral particles. The recovered virus differs biologically from P3HR-1 EBV since it transforms human umbilical cord blood lymphocytes into EBNA-positive lymphoblastoid cell lines. Cells of these established lines are susceptible to renewed infection by P3HR-1 EBV which results in EA induction and VCA synthesis. Only cells of one line, NC37-R1, spontaneously produce VCA and EBV particles, which reveal transforming properties and do not induce EA upon superinfection of Raji cells. Infection of P3HR-1 EBV-converted BJA-B cells also leads to EA and VCA induction and the release of viral particles. In contrast to particles recovered from Raji and NC37 cells, no transforming activity was detectable in these virus preparations. According to these data, we propose that viral genomes persisting within Raji and NC37 cells are defective and become complemented by the superinfecting P3HR-1 virus.

Activation of endogenous type C virus in BALB/c mouse cells by herpesvirus DNA

Several virion and nonvirion DNAs were tested for the ability to activate endogenous type C virus in BALB/c-derived mouse cells using the calcium precipitation technique. The DNAs from all herpesviruses tested activated xenotropic type C virus synthesis. These included DNAs from herpes simplex virus types 1 and 2, Epstein-Barr virus, human cytomegalovirus, SA8 virus, infectious bovine rhinotracheitis virus, pseudorabies virus, and herpes saimiri virus (M-DNA). In contrast, DNAs from vaccinia virus, simian virus 40, primate cells, bacteria, mycoplasma, and salmon sperm showed no ability to activate type C virus when tested under the same conditions. Several herpesviruses and vaccinia virus, which were highly infectious for the BALB/c cells used, were tested for their ability to activate type C virus after UV irradiation. All herpesviruses tested were positive, while vaccinia virus was negative. Unirradiated simian virus 40 also showed no ability to activate type C virus. Activation of type C virus by DNA from herpes simplex virus was observed after shearing or sonication of the DNA to an average size of 3 x 10(6) daltons, but was not observed with DNA sonicated to an average size of 1 x 10(6) daltons. Alkali denaturation of DNA from herpes simplex virus or treatment with DNase, but not RNase, destroyed its ability to activate type C virus, as did crosslinking of the DNA with 4,5',8-trimethylpsoralen (psoralen) and light.

Transforming activity of Epstein-Barr virus obtained by superinfection of Raji cells

Epstein-Barr virus obtained by superinfection of Raji cells with Epstein-Barr virus recovered from P3HR1 cells (HRI virus) transformed human lymphocytes, but it did not superinfect Raji cells. A human lymphoblastoid cell line, HLB, established by such transformation contained 22 Epstein-Barr virus genomes per cell and Epstein-Barr virus-associated nuclear antigen, and a few cells contained early or viral capsid antigen complexes. Chromosomal analysis revealed that HLB-cells were diploid with normal female karyotypes. Replication of Epstein-Barr virus DNA and inhibition of host cell DNA synthesis were observed in HLB cells after superinfection with HR1 virus.

Replication of Epstein-Barr virus: ultrastructural and immunofluorescent studies of P3HR1-superinfected Raji cells

We have studied by means of electron microscopy and immunofluorescence the different steps of the replication of the P3HR1 strain of Epstein-Barr virus in Raji cells. The virus entered the cell by fusion of the viral envelope with the plasma membrane, followed by the disintegration of the capsid. In some cases, the migration of nucleocapsids toward the nuclear membrane was observed. The synthesis of new virions began as early as 7 h after infection (in the case of a high multiplicity of infection [MOI]-800 particles per cell) and took place in low-electron-density areas of the nucleus. A viral envelope was acquired by budding either through the nuclear membrane or more often through membranes of the Golgi apparatus or cytoplasmic vacuoles. Comparing immunofluorescence and electron microscopic data a good correlation was found between the presence of early antigen and ultrastructurally altered cells, as well as between the presence of viral capsid antigen and virus-producing cells. With different MOIs, different types of viral cycles were observed: at a low MOI (less than or equal to 50 particles per cell), a nonproducer cycle was induced, with early antigen synthesis only; at a higher MOI (100 particles per cell), a transient production of a small amount of virions was observed, and at a high MOI (greater than or equal to 300 particles per cell), a productive cycle was the rule.

Epstein-barr virus-specific RNA. II. Analysis of polyadenylated viral RNA in restringent, abortive, and prooductive infections

The complexity and abundance of Epstein-Barr (EBV)-specific RNA in cell cultures restringently, abortively, and productively infected with EBV has been analyed by hybridization of the infected cell RNA with purified viral DNA. The data indicate the following. (i) Cultures containing productively infected cells contain viral RNA encoded by at least 45% of EBV DNA, and almost all of the species of viral RNA are present in the polyadenylated and polyribosomal RNA fractions. (ii) Restringently infected Namalwa and Raji cultures, which contain only intranuclear antigen, EBNA, and enhanced capacity for growth in vitro, contain EBV RNA encoded by at least 16 and 30% of the EBV DNA, respectively. The polyadenylated and polyribosomal RNA fractions of Raji and Namalwa cells are enriched for a class of EBV RNA encoded by approximately 5% of EBV DNA. The same EBV DNA sequences encode the polyadenylated and polyribosomal RNA of both Raji and Namalwa cells. (iii) After superinfection of Raji cultures with EBV (HR-1), the abortively infected cells contain RNA encoded by at least 41% of EBV DNA. The polyadenylated RNA of superinfected Raji cells is enriched for a class of EBV RNA encoded by approximately 20% of EBV HR-1 DNA. Summation hybridization experiments suggest that the polyadenylated RNA in superinfected Raji cells is encoded by the same DNA sequences as encode RNA present in Raji cells before superinfection, most of which is not polyadenylated. That the same EBV RNA sequences are present in the polyadenylated and polyribosomal fractions of two independently derived, restringently infected cell lines suggests that these RNAs may specify functions related to maintenance of the transformed state. The complexity of this class of RNA is adequate to specify a sequence of a least 5,000 amino acids. That only some RNA species are polyadenylated in restringent and abortive infection suggests that polyadenylation or whatever determines polyadenylation may play a role in the restricted expression of the EVB genome.