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

The latent membrane protein 1 of Epstein-Barr virus establishes an antiviral state via induction of interferon-stimulated genes

Epstein-Barr virus (EBV) infection is associated with several human cancers. Latent membrane protein 1 (LMP-1) is one of the key viral proteins required for transformation of primary B cells in vitro and establishment of EBV latency. In this report, we show that LMP-1 is able to induce the expression of several interferon (IFN)-stimulated genes (ISGs) with antiviral properties such as 2'-5' oligoadenylate synthetase (OAS), stimulated trans-acting factor of 50 kDa (STAF-50), and ISG-15. LMP-1 inhibits vesicular stomatitis virus (VSV) replication at low multiplicity of infection (0.1 pfu/cell). The antiviral effect of LMP-1 is associated with the ability of LMP-1 to induce ISGs; an LMP-1 mutant that cannot induce ISGs fails to induce an antiviral state. High levels of ISGs are expressed in EBV latency cells in which LMP-1 is expressed. EBV latency cells have antiviral activity that inhibits replication of superinfecting VSV. The antiviral activity of LMP-1 is apparently not related to IFN production in our experimental systems. In addition, EBV latency is responsive to viral superinfection: LMP-1 is induced and EBV latency is disrupted by EBV lytic replication during VSV superinfection of EBV latency cells. These data suggest that LMP-1 has antiviral effect, which may be an intrinsic part of EBV latency program to assist the establishment and/or maintenance of EBV latency.

Identification of a naturally occurring recombinant Epstein-Barr virus isolate from New Guinea that encodes both type 1 and type 2 nuclear antigen sequences

In this report we describe an Epstein-Barr virus isolate, derived from the peripheral blood lymphocytes of a healthy adult from Papua New Guinea, that is a recombinant of the two major Epstein-Barr virus types, encoding type 1 Epstein-Barr nuclear antigen 2 (EBNA2) sequences, and type 2 EBNA3, EBNA4, and EBNA6 sequences.

Synchronous and sequential activation of latently infected Epstein-Barr virus genomes

A lymphoid cell system was established that can induce the prompt and synchronous activation of latent Epstein-Barr virus (EBV) genomes and thus allows the identification of viral genes that are activated sequentially depending on their functions. With this system, we proved that disruption of EBV latency is initiated by activation of four EBV genes and that protein synthesis is not required prior to activation of latent EBV. The system should be an in vitro model for studying the mechanism of herpesvirus latency.

Antigenic variation in alkaline deoxyribonuclease induced by three different strains of Epstein-Barr virus

To determine whether biological and/or biochemical variants exist between strains of Epstein-Barr virus (EBV), we superinfected Raji cells with the nontransforming lytic strain of EBV (HR-1), and two isolates that both transform B-lymphocytes and superinfect Raji cells, B95-8, and NPC-EBV. The superinfected cells were assayed for EBV specific DNase. A new electrophoretic form of DNase was observed in cells superinfected with B95-8 EBV as compared to the enzymes induced by the HR-1 and NPC-EBV isolates. There were antigenic differences in the DNase induced by the EBV strains. Since antibody to EBV DNase is a marker for nasopharyngeal carcinoma (NPC), these data may have implications for EBV-associated disease.

Two strains of Epstein-Barr virus (B95-8 and a P3HR-1 subclone) that lack defective genomes induce early antigen and cause abortive infection of Raji cells

The heterogeneity of Epstein-Barr virus (EBV) obtained from P3HR-1 cells has permitted derivation of a distinct subclone of P3HR-1 (L. Heston, M. Rabson, N. Brown, and G. Miller, Nature (London) 295:160-163, 1982). We have analyzed the biologic properties and genomic structure of this subclonal virus (clone 13) compared with those of parental P3HR-1 and B95-8 viruses. Synthesis of EBV compared with those of parental P3HR-1 and B95-8 viruses. Synthesis of EBV proteins in Raji cells superinfected with virus derived from P3HR-1, clone 13, and B95-8 was analyzed both by fluorography of radiolabeled proteins and by immunoblotting. Highly concentrated preparations of clone 13 and B95-8 virus induced most of the spectrum of EBV proteins in Raji cells with the exception of the 145,000-, 140,000-, and 110,000-molecular-weight proteins, which were either undetectable or reduced. Moreover, both clone 13 and B95-8 viruses also induced the same patterns of early antigen diffuse components as the parental P3HR-1 virus did. However, only P3HR-1 virus could induce EBV DNA synthesis in superinfected Raji cells, as determined both by buoyant density centrifugation and by in situ cytohybridization with biotinylated recombinant EBV DNA probes. Defective heterogeneous molecules present in P3HR-1 virus have been implicated in early antigen induction after superinfection of Raji cells. Therefore, Southern blots of clone 13, P3HR-1, and B95-8 viruses were hybridized to recombinant EBV fragments representing the sequences contained within the defective molecules in P3HR-1. The parental P3HR-1 contained the previously described defective molecules. No evidence for defective molecules was found in clone 13 or B95-8 viruses. These data indicate that concentrated preparations of both clone 13 and B95-8 viruses can induce abortive infection in Raji cells, but while the defective molecules are not needed for induction of early antigen diffuse components, they may be required for the induction of viral DNA synthesis.

An Epstein-Barr virus (EBV)-determined nuclear antigen (EBNA5) partly encoded by the transformation-associated Bam WYH region of EBV DNA: preferential expression in lymphoblastoid cell lines

Four peptides were synthesized on the basis of amino acid sequences deduced from a highly spliced transcript encoded by the Bam W, Y, and H fragments of the Epstein-Barr virus (EBV) genome [Bodescot, M., Chambraud, J. B., Farrell, P. J. & Perricaudet, M. (1984) EMBO J. 3, 1913-1917]. Rabbit antisera against three of the four peptides identified a nuclear polypeptide that varied between 22 and 70 kDa in molecular size. Four of 20 EBV-positive human sera contained antibodies against this polypeptide. Since this is the fifth EBV-determined nuclear antigen (EBNA) discovered in growth-transformed cells, it is designated EBNA5. The antigen was detected in virus nonproducer lines (less than 0.01% EBV early antigen expression) and is thus not dependent on the viral cycle. It was differentially expressed depending on the origin of the lines. All 10 lymphoblastoid cell lines tested expressed EBNA5, but it could not be detected in 10 of 11 EBV-carrying Burkitt lymphoma lines. Infection of tonsillar lymphocytes with the B95-8 strain of EBV induced six EBNA5-specific polypeptides that varied between 41 and 70 kDa in molecular size with regular increments of 6 kDa. This may be due to the fact that the EBNA5 coding sequence includes the Bam W internal repeat. Parallel infection of the EBV-negative Burkitt lymphoma line Ramos with the same viral substrain did not induce detectable levels of EBNA5, nor was this antigen present in permanently EBV-converted Ramos sublines. These findings imply that the expression of the viral genome varies among B cells having different phenotypes.

Epstein-Barr virus-specific DNA polymerase in virus-nonproducer Raji cells

Virus-nonproducer Raji cells, when induced to early antigen synthesis by 12-O-tetradecanoyl-phorbol-13-acetate and sodium butyrate, showed an increase in DNA polymerase activity. This enzyme has the characteristics of a typical Epstein-Barr virus DNA polymerase with regard to chromatographical pattern and biological properties: it is eluted from DEAE-cellulose at 0.08 M NaCl, has a high salt resistance, is sensitive to phosphonoacetic acid and phosphonoformate, and shows a substrate preference for poly(dC)-oligo(dG12-18). The resistance of Epstein-Barr virus polymerase activity to aphidicolin is a property distinct from that of HSV DNA polymerase. Viral DNA polymerase activity increases in the absence of Epstein-Barr virus DNA replication, indicating that this enzyme is an early viral protein.

Transformation by Epstein-Barr virus requires DNA sequences in the region of BamHI fragments Y and H

Eight independent recombinant Epstein-Barr virus genomes, each of which was a transforming strain, were made by superinfecting cell lines containing Epstein-Barr virus DNA (Raji or B95-8 strain) with a nontransforming virus (P3HR1 strain). A knowledge of the constitution of each transforming recombinant allowed the localization of the defect in the genome of the nontransforming parent to a 12-megadalton sequence within the EcoRI A fragment. Within this region, the nontransforming virus has a deletion of the BamHI Y fragment and about half of the sequences in the adjacent BamHI H fragment. The present data suggest that this deletion is responsible for the nontransforming phenotype. Furthermore, mapping a deletion in one of the recombinant genomes allowed the conclusion that a sequence (comprising about 20% of the Epstein-Barr virus genome) from the center of BamHI-D to BamHI-I' is not necessary for the maintenance of transformation by Epstein-Barr virus.

Antibodies against synthetic peptides react with the second Epstein-Barr virus-associated nuclear antigen

Five peptides were synthesized on the basis of amino acid sequences predicted from the transformation-associated BamHI WYH region of the genome of the Epstein-Barr virus (EBV). Antisera to two peptides deduced from a 1.6-kb open reading frame in the BamHI H fragment identified an 87 000-dalton nuclear polypeptide that was present in EBV-carrying cell lines that expressed the second EBV-determined nuclear antigen (EBNA-2). This polypeptide was not detected in cell lines that carried EBV variants with a deleted BamHI WYH region or in EBV-negative cell lines. Three peptides deduced from the 1.6-kb open reading frame reacted with human EBNA-positive sera, but not with EBNA-negative sera. Following affinity purification with the peptides, two of the corresponding human antibodies also reacted with the 87 000-dalton polypeptide.

Characterization of a second Epstein-Barr virus-determined nuclear antigen associated with the BamHI WYH region of EBV DNA

The Epstein-Barr virus-determined nuclear antigen (EBNA) is the only known virally-determined component that is regularly associated with EBV-transformed cells. A main component of EBNA, herein designated EBNA-1, has been conclusively localized to the BamHI K fragment of the viral genome. EBNA-1 is present in all EBV-carrying cell lines so far studied. Our current study deals with a second component. We have found that the EBNA reaction detected by anti-complement immunofluorescence (ACIF) in Burkitt lymphoma lines Daudi, Jijoye, and P3HR-1 could be completely removed by preabsorption of sera with any one of these 3 lines, when tested against any other of them. The same absorbed sera still gave a brilliant nuclear staining against other EBV-carrying lines, e.g. Raji or B95-8. The 3 lines in the first category carry EBV genomes that have deletions in the BamHI WYH region of the EBV genome. This region is intact in the second group of lines. This result is interpreted as showing the existence of 2 different ACIF-stainable EBV-determined nuclear antigens, one of which is associated with the BamHI WYH region. We designate this antigen as EBNA-2. We found that the two different EBNAs are different with regard to their association with metaphase chromosomes. In lines positive for both EBNA subtypes, metaphase chromosomes gave brilliant EBNA-1 staining, but could not be stained for EBNA-2, indicating differences in chromatin association of the two EBNAs. An 86 kd polypeptide was identified by immunoblotting of DNA-binding proteins from EBV-transformed lymphoid cell lines. EBV-specificity of the polypeptide was demonstrated by the presence of antibodies against this polypeptide in antisera from a population of EBV-seropositive donors, but not from seronegative donors, by the presence of the polypeptide itself in EBV-carrying but not in EBV-negative cell lines and by the appearance of antibodies against this polypeptide during the course of infectious mononucleosis (IM). The polypeptide was absent from the EBV-carrying P3HR-1, Daudi and Jijoye cell lines, which suggested that it may be encoded by the BamHI WYH region that is deleted from the viral substrains carried by these lines.

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.

Identification of a rare Epstein-Barr virus variant that enhances early antigen expression in Raji cells

Early antigens (EAs) are made when the P3J-HR-1 strain of Epstein-Barr virus (EBV) infects cells that already harbor latent EB viral genomes. We wished to identify EBV genes that might participate in induction of EAs. We have recently isolated from the HR-1 line EB viral variants that are unable to induce EAs. We have now isolated a clone of HR-1 cells that releases virus with the capacity to induce EA. We compared the genome of the EB variant that possesses the capacity to induce EA with that of a variant that is unable to induce EA and with parental stock that was the source of both different biotypes of EBV. The variant that is able to induce EA contains, in molar or greater quantities, additional fragments of EBV DNA not found in the variant that lacks that capacity. These same DNA fragments are present in submolar quantities in the parental DNA, indicating that they represent a subpopulation in the parental viral DNA mixture. We thus provide evidence that EA induction is brought about by unusual forms of EBV DNA that are likely to act by regulating expression of the genome.

Rescue of transforming Epstein-Barr virus (EBV) from EBV-genome-positive epithelial hybrid cells transfected with subgenomic fragments of EBV DNA

Transfection experiments using subgenomic fragments of the B95-8 strain of Epstein-Barr virus (EBV) DNA and EBV genome (HR-1)-positive epithelial/Burkitt hybrid cells (D98/HR-1) were carried out to determine whether an interaction between the transfecting virus fragment(s) and the endogenous HR-1 EBV genome could take place. Expression of EBV-specific antigens, including early antigen and virus capsid antigen, was examined in transfected cells by immunofluorescence. Attempts were also made to recover biologically active EBV from the D98/HR-1 cells after transfection with cloned fragments of B95-8 DNA. We found that D98/HR-1 cells transfected with the BamHI H or H, F, and X fragments were positive for early antigen 3 days after transfection. Spent media from transfected D98/HR-1 cells maintained for 20-30 days in culture were pooled, filtered, concentrated, and used as a potential source of virus to inoculate human umbilical cord blood lymphocytes. No evidence of transformation was observed with such preparations. However, if spent medium from D98/HR-1 cell cultures was first treated with iododeoxyuridine (to induce EBV DNA synthesis and replicative cycle) and then transfected with the BamHI H, F, and X fragments of B95-8 DNA and used to infect cord blood lymphocytes, transformation was obtained. A lymphoblastoid cell line derived in this manner, designated HI-HFX, is an EBV nuclear antigen-positive nonproducer cell line. Similar results were obtained with preparations from iododeoxyuridine-treated D98/HR-1 cells transfected with the EB 26-36 fragment of B95-8 DNA cloned in a Charon 4A vector. The EB 26-36 fragment contains the BamHI H, F, and X regions.

Non-immortalizing P3J-HR-1 Epstein-Barr virus: a deletion mutant of its transforming parent, Jijoye

The P3J-HR-1 strain of Epstein-Barr virus (EBV) fails to immortalize human lymphocytes. We wished to understand the nature of the genomic alterations which correlated with the loss of this ability. As a first step, the heterogeneity of DNA molecules in the P3J-HR-1 line was eliminated by cell cloning. Then a physical map was prepared of virion DNA from one cell clone, designated FF452-3. By comparison with the genomes of two EBVs, B95-8 and FF41, which are competent to immortalize lymphocytes, we identified a total of eight modifications of BamHI and EcoRI restriction endonuclease fragments of EBV (FF452-3) DNA consisting of insertions, deletions, or loss of a restriction endonuclease recognition site. To determine which of these alterations might be responsible for the loss of transforming phenotype, we examined homologous DNA fragments of the Jijoye strain of EBV, the progenitor of the HR-1 strain which still retains the ability to immortalize lymphocytes. We also studied viral DNA in lymphocytes transformed in vitro by Jijoye virus. Six of the eight alterations were found both in Jijoye and in clonal HR-1 DNA and were presumably genomic traits characteristic of this lineage of EBV. A small deletion in the BamHI-K fragment of HR-1 DNA was not found in Jijoye virion DNA, but this deletion was present in intracellular Jijoye DNA. Thus only one major genomic lesion in HR-1 DNA, a deletion of at least 2.4 x 10(6) molecular weight of DNA from a fused BamHI-H-Y fragment, consistently distinguished Jijoye DNA from its non-immortalizing P3J-HR-1 derivative. This deletion is likely to affect EBV genes which are directly or indirectly involved in immortalizing lymphocytes.

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.

Deletion of the nontransforming Epstein-Barr virus strain P3HR-1 causes fusion of the large internal repeat to the DSL region

The nontransforming Epstein-Barr virus (EBV) strain P3HR-1 is known to have a deletion of sequences of the long unique region adjacent to the large internal repeats. The deleted region is believed to be required for initiation of transformation. To establish a more detailed map of the deletion in P3HR-1 virus, SalI-A of the transforming strain M-ABA and of P3HR-1 virus was cloned into the cosmid vector pHC79 and multiplied in Escherichia coli. The cleavage sites for BamHI, BglII, EcoRI, PstI, SacI, SacII, and XhoI were determined in the recombinant plasmid clones. Analysis of the boundary between large internal repeats and the long unique region showed that in M-ABA (EBV) the transition is different from that in B95-8 virus. The map established for SalI-A of P3HR-1 virus revealed that, in contrast to previous reports, the deletion has a size of 6.5 kilobase pairs. It involves the junction between large internal repeats and the long unique region and includes more than half of the rightmost large internal repeat. The site of the deletion in the long unique region is located between a SacI and a SacII site, about 200 base pairs apart from each other. The sequences neighboring the deletion in the long unique region showed homology to the nonrepeated sequences of the DS(R) (duplicated sequence, right) region. Sequences of the large internal repeat are thus fused to sequences of the DS(L) (duplicated sequence, left) region in P3HR-1 virus DNA under elimination of the DS(L) repeats. Jijoye, the parental Burkitt lymphoma cell line from which the P3HR-1 line is derived by single-cell cloning, is known to produce a transforming virus. Analysis of the Jijoye (EBV) genome with cloned M-ABA (EBV) probes specific for the sequences missing in P3HR-1 virus revealed that the sequences of M-ABA (EBV) BamHI-H2 are not represented in Jijoye (EBV). In Jijoye (EBV) the complete DS(L) region including the DS(L) repeats is, however, conserved. Further analysis of Jijoye (EBV) and of Jijoye virustransformed cell lines will be helpful to narrow down the region required for transformation.

Identification of Epstein-Barr virus strain differences with monoclonal antibody to a membrane glycoprotein

Two monoclonal antibodies directed against Epstein--Barr virus (EBV)-induced membrane antigens (MA) were isolated in this study. On of the monoclonal antibodies, designated 2F5.6, was an IgG2 which, as detected by membrane and fixed cell immunofluorescence, reacted with MA-positive lymphoblastoid cell lines that produced transforming EBV but not with the MA-positive P3HR-1 cell line that produced the lytic, nontransforming strain of this virus. This antibody precipitated the Mr 320,000/350,000 glycoprotein from B-95 virus infected cultures and the Mr 300,000 and 220,000/250,000 glycoproteins from Raji cells superinfected with P3HR-1 virus but did not precipitate any of these EBV-specific glycoproteins from the P3HR-1 cell line. In contrast, the second monoclonal antibody, IgM designated B10.3, reacted with all virus-producing cell lines including the P3HR-1 cell line. The identity of the glycoprotein that serves as the target for this antibody is still unknown. Neither antibody had neutralizing activity against the B-95 or P3HR-1 strain of EBV. These results indicated that the 2F5.6 monoclonal antibody was directed against an antigenic determinant on the major membrane glycoprotein which is common to transforming strains of EBV but absent from the lytic P3HR-1 stain whereas the B10.3 monoclonal antibody was directed against a group-specific EBV-induced membrane determinant.

Epstein-Barr virus DNA. IX. Variation among viral DNAs from producer and nonproducer infected cells

A comparative analysis of three Epstein-Barr virus DNAs from American patients with infectious mononucleosis (B95-8, Cherry, and Lamont) and four Epstein-Barr virus DNAs from African patients with Burkitt lymphoma (AG876, W91, Raji, and P3HR-1) indicated that the usual format of Epstein-Barr virus DNA includes a variable number of direct repeats of a 0.35 X 10(6)-dalton sequence (TR) at both ends of the DNA, a 9 X 10(6)-dalton sequence of largely unique DNA (Us), a variable number of repeats of a 2 X 10(6)-dalton sequence (IR), and a 89 X 10(6)-dalton sequence of largely unique DNA (UL). Within UL there was homology between DNA at 26 X 10(6) to 28 X 10(6) daltons and DNA at 93 X 10(6) to 95 X 10(6) daltons. The relative sequence order (TR, US, IR, UL, TR) did not vary among "standard" Epstein-Barr virus DNA molecules of each isolate. B95-8 DNA had an unusual deletion extending from 91 X 10(6) to 100 X 10(6) daltons, and P3HR-1 DNA had an unusual deletion extending from 23.5 X 10(6) to 26 X 10(6) daltons. There was sufficient variability among the EcoRI and BamHI fragments of the DNAs to identify each isolate specifically. However, we discerned no distinguishing features for the two geographic or pathogenic origins of the seven isolates. Three intracellular DNAs (Raji, Lamont, and Cherry) and one virion DNA (P3HR-1) were heterogenous in molecular organization and had subpopulations of rearranged or defective molecules. Some regions, particularly 59 X 10(6) to 63 X 10(6) daltons and sequences around TR, frequently participated in rearrangements. Restriction endonuclease maps of the standard and rearranged DNAs of the seven isolates are presented.

Syncytium-forming virus of common marmosets (Callithrix jacchus jacchus)

This communication describes the isolation and characterization of a new syncytium-forming virus of common marmosets (Callithrix jacchus jacchus). The virus, isolated from skin explants and peripheral leukocytes of healthy animals, induced syncytia and subsequent cytolysis of several human, simian, and rodent fibroblastic cultures and induced a carrier state in mixed fibroblastic-epithelial or epithelial cell lines. Cytoplasmic and nuclear viral antigen was demonstrated in infected cells by indirect immunofluorescence tests using serum obtained from persistently infected common marmosets. Abundant virus particles were detected within cisternae of endoplasmic reticulum of lytically infected cells by electron microscopy. The virus incorporated [3H]uridine, banded at a density of 1.14 to 1.16 g/cm3 in sucrose, and possessed ribonucleic acid-dependent deoxyribonucleic acid polymerase. No antigenic cross-reactivity was detected between the marmoset virus and simian foamy virus serotypes 1 to 8 in neutralization and immunofluorescence assays. A seroepidemiological survey of a marmoset colony revealed that 53.5% of common marmosets contained antibodies against the virus, whereas other species of marmosets maintained in the same colony remained free of antibodies.

Multiplicity-dependent biological and biochemical properties of Epstein-Barr virus (EBV) rescued from non-producer lines after superinfection with P3HR-1 EBV

Superinfection of lymphoblastoid cells of EBV non-producer lines with non-transforming P3HR-1 EBV leads to the rescue of transforming virus. At least part of the recovered molecules represent recombinant DNA between superinfecting P3HR-1 EBV and resident viral genomes (Fresen et al., 1979, 1980). With high titer stocks of superinfecting P3HR-1 EBV, viral particles with early antigen (EA)-inducing properties can be rescued, indicating that under these conditions of infection input viral genomes may become replicated. Sequential blot analysis with 32P-P3HR1-EBV DNA of intracellular viral DNA synthesized following infection reveals a multiplicity-dependent pattern. High particle inputs lead to preferential synthesis of certain fragments, independent of infection of either EBV genome-free or EBV genome carrier cells. This accumulation of specific viral sequences indicates defective replication of P3HR-1 EBV DNA.

Re-evaluation of a transforming strain of Epstein-Barr virus from the Burkitt lymphoma cell line, Jijoye

The biological properties of Epstein-Barr virus (EBV) from a Burkitt lymphoma cell line, Jijoye, were examined. the synthesis of virus capsid antigen (VCA) and early antigen (EA) in Jijoye cells was markedly enhanced by shift-down of the temperature of incubation from 37 degrees C to 33 degrees C. Cultures of Jijoye cells at 33 degrees C released a large amount of transforming EBV (10(5.2) of 50% transforming doses/ml) into the culture fluid. However, no infectious virus was produced in all cultures at 37 degrees C during the course of this study. The EBV (Jijoye EBV) from Jijoye line was found to possess only transforming activity, but not EA-inducing activity. Jijoye EBV lacks adsorbing capacity to Jijoye cells, in contrast to P3HR-I EBV which can adsorb to Jijoye cells. The Jijoye cells were highly susceptible to superinfection with P3HR-I EBV as demonstrated by the induction of EA, VCA and infectious EBV. The EBV induced by the P3HR-I EBV superinfection of Jijoye cells has also transforming activity but neither EA-inducing activity nor adsorbing capacity to Jijoye cells.

Infection and persistence of varicella-zoster virus in lymphoblastoid Raji cell line

Infection of Raji cells by varicella-zoster virus (VZV) resulted in permissive infection with establishment of a persistently infected lymphoblastoid cell line. VZV antigens of the membrane and nuclear type, as detected by the indirect immunofluorescence membrane antigen (IFAMA) and anticomplement immunofluorescence (ACIF) tests, were observed. Minute amounts of infectious virus were detected by co-cultivation of VZV-infected Raji cells (Raji-VZV), with permissive human embryo fibroblasts (HEF). The virus isolated was found to be similar to the parent strain. Transient induction of Epstein-Barr viral capsid antigen (EB-VCA) was also observed. The persistently infected Raji-VZV cell line, when free of EB-VCA, was found suitable for measuring antibodies to varicella-zoster virus. The possible interaction in the infected Raji cells between EBV, which is implicated in human malignancy, and VZV which belongs also to the herpes group of viruses, is discussed.

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.