Epstein-Barr virus DNA synthesized in superinfected Raji cells

Genomic characterization of the virus causing infectious salmon anemia in Atlantic salmon (Salmo salar L.): an orthomyxo-like virus in a teleost

The genome of infectious salmon anemia virus (ISAV), which infects farmed Atlantic salmon (Salmo salar L.), is characterized here. The virus has an RNA genome, as shown by using specific DNA virus metabolic inhibitors and radioactive in vivo labeling of ISAV nucleic acid. Electrophoresis of [14C]uridine-labeled ISAV RNA revealed that the ISAV genome is segmented. The genome consists of eight segments that range from 1.0 to 2.3 kb, with a total molecular size of approximately 14.5 kb. One ISAV-specific molecular clone, corresponding to the smallest genome segment, was obtained by cDNA cloning of mRNA from an ISAV-infected cell culture. This clone gave a positive hybridization signal on Northern blots of pelleted ISAV. Pretreatment of the ISAV pellet with RNase A resulted in the disappearance of the positive hybridization signal, demonstrating that the genome is single stranded. Reverse transcriptase PCR with primers corresponding to sequences from the molecular clone and target RNA from ISAV-infected and noninfected fish tissues gave specific positive reactions. Alignments of the nucleotide sequence of the molecular clone did not reveal significant homology with any other available sequence in databases. However, the data presented here, together with morphological and replicational properties previously described, indicate that ISAV has a strong resemblance to members of the Orthomyxoviridae family. This is the first thoroughly characterized orthomyxo-like virus isolated from a teleost.

Construction and use of cDNA clones for the mapping and identification of Epstein-Barr virus early P3HR-1 mRNAs

cDNA clones, specific for early Epstein-Barr virus (EBV) RNAs, were constructed from total cytoplasmic RNA of P3HR-1 TK- cells. From 10,000 cDNA clones screened, 22 virus-specific cDNA clones were selected by hybridization with a total EBV DNA. These clones were then precisely mapped on the EBV genome and the corresponding mRNAs were identified by Northern blot hybridizations. Most of them are clearly related to some of the open reading frames described by Baer et al. (Nature [London] 310:207-211, 1984). They represent at least 18 different genes active during the early viral cycle. The transcriptional activity of the virus during the early stage was also studied by dot blot hybridization of total early cDNA probe to EBV genomic fragments. Three main regions showed very strong hybridization with the cDNA probe: BamHI a, M, and L fragments, BamHI K, B, and G fragments, and BamHI B1 fragment (deleted in strain B95-8) and the adjacent right end of the DNA molecule. Seventeen of the cDNA clones were localized in these highly transcribed regions. The five others were dispersed all along the EBV 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.

Detection of autonomous replicating sequences (ars) in the genome of Epstein-Barr virus

Epstein-Barr virus (EBV) DNA was analyzed for the presence of autonomous replicating sequences (designated ars) in a eukaryotic system consisting of a uracil auxotroph of Saccharomyces cerevisiae, YNN27, and a pBR322 hybrid plasmid, YIp5, containing the yeast uracil gene but apparently lacking a eukaryotic origin of replication. Cloned EBV DNA EcoRI restriction fragments, A, B, and DIJhet, were judged to function in this capacity by their ability to convert YNN27 cells to the uracil phenotype after transformation with each EBV-specific fragment ligated into YIp5. Additional analyses to confirm and to specify further the location of the ars were performed by cleavage of EcoRI fragments A and B into smaller BamHI fragments, which were subsequently cloned in YIp5 and tested for their ability to function as ars. BamHI fragment X, obtained from EcoRI fragment A, and BamHI fragment R, obtained from EcoRI fragment B, showed ars behavior. The successful recovery of the appropriate virus DNA segments in plasmid form from transformed yeast cells and the ability of these yeast cells to be propagated further substantiated the ars capability of the three EBV fragments.

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.

Incorporation into DNA of the base analog 2-aminopurine by the Epstein-Barr virus-induced DNA polymerase in vivo and in vitro

The Epstein-Barr virus (EBV)-induced intracellular DNA polymerase was assayed in vitro for the ability to utilize the mutagenic nucleotide analog 2-aminopurine deoxyribose triphosphate (d2apTP), incorporating it as the corresponding monophosphate into DNA or poly[d)(A-T)] template. Bacteriophage T4, lymphocyte alpha, and the EBV particle-associated DNA polymerases were assayed simultaneously for direct comparison. Unlike these three polymerases, which were capable of distinguishing between d2apTP and dATP with a strong preference for the latter, the EBV-induced DNA polymerase only weakly distinguished between dATP and d2apTP and incorporated substantial amounts of d2apTP into template. Detergent-treated lymphocyte nuclei undergoing a high level of EBV DNA synthesis were shown to incorporate the 2-aminopurine analog of dATP into viral DNA. The relative inability of the EBV-induced DNA polymerase to distinguish between the two purine nucleotides reported here is consistent with previous reports on the ready incorporation of other nucleotide analogs into DNA polymerases induced by other herpesviruses. Because most antiherpes agents currently in use or under study are nucleotide analogs, the viral mutagenic properties of these drugs should be examined.

Characterization of the Epstein-Barr virion-associated DNA polymerase as isolated from superinfected and drug-stimulated cells

We reported previously that Epstein-Barr (EB) virions and detergent-treated nucleocapsids co-purified with significant amounts of DNA polymerase activity that did not resemble other known host or viral polymerases. We report here that this species of DNA polymerase activity is present at early times after infection in lymphocytes abortively lytically infected (superinfected) with EB virus. However, studies with [35S]methionine labeling suggest de novo synthesis of enzyme has not occurred. Conversely, drug-stimulated lymphocytes that synthesize EB viral late proteins and virions contain this species of polymerase to the virtual exclusion of all others. This EB viral polymerase shows a marked preference for nicked and gapped double-stranded rather than primed single-stranded DNA templates. Its processiveness as measured on primed theta X174 phage DNA template is lower than that of lymphocyte beta polymerase. The data reported here are consistent with the hypothesis that the EB virion-associated DNA polymerase is synthesized at late times in the viral life cycle as are other structural proteins but it plays an important role early after viral infection. It is known that mature herpes virion DNA (including that of EB virus) is nicked and gapped and we propose that virion polymerase repairs the viral DNA at an early stage in infection before viral DNA replication begins.

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.

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.

Comparison of Epstein-Barr virus strains of different origin by analysis of the viral DNAs

Epstein-Barr virus (EBV) originating from Burkitt's lymphoma (P3HR-1 and CC34-5), nasopharyngeal carcinoma (M-ABA), transfusion mononucleosis (B95-8), and a patient with acute myeloblastic leukemia (QIMR-WIL) was isolated from virus-carrying lymphoid cell lines after induction with the tumor promoter 12-O-tetradecanoylphorbol-13-acetate. Viral DNA was analyzed by partial denaturation mapping and by use of the restriction endonucleases EcoRI, HindIII, and SalI and separation of fragments in 0.4% agarose. By using the restriction enzyme data of B95-8 (EBV) and W91 (EBV) obtained by Given and Kieff (D. Given and E. Kieff, J. Virol. 28:524-542, 1978), maps were established for the other virus strains. Comigrating fragments were assumed to be identical or closely related among the different strains. Fragments of different strains migrating differently were isolated, purified, radioactively labeled, and mapped by hybridization against blots of separated viral fragments. The results were as follows. (i) All strains studied were closely related. (ii) The number of internal repeats was variable among and within viral strains. (iii) B95-8 (EBV) was the only strain with a large deletion of about 12,000 base pairs at the right-hand side of the molecule. At the same site, small deletions of about 400 to 500 base pairs were observed in P3HR-1 (EBV) and M-ABA (EBV) DNA. (iv) P3HR-1 (EBV), the only nontransforming EBV strain, had a deletion of about 3,000 to 4,000 base pairs in the long unique region adjacent to the internal repeats carrying a HindIII site. (v) Small inserted sequences of 150 to 400 base pairs were observed in M-ABA (EBV) and B95-8 (EBV) at identical sites in the middle of the long unique region. (vi) Near this site, an insertion of about 1,000 base pairs was found in P3HR-1 (EBV) DNA. (vii) The cleavage patterns of P3HR-1 virus DNA and the results of blot hybridizations with P3HR-1 virus fragments are not conclusive and point to the possibility that in addition to the normal cleavage pattern some viral sequences may be arranged differently. Even though it is possible that small differences in the genome organization may have significant biological effects, the great similarity among different EBV strains does not favor the hypothesis that disease-specific subtypes exist.

Polypeptide synthesis and phosphorylation in Epstein-Barr virus-infected cells

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, results in the sequential synthesis of 29 detectable proteins, which range in molecular weight from approximately 155,000 to 21,000, and in the shutoff of the bulk of host protein synthesis within 6 to 9 h after infection. There are three classes of virus-induced proteins; these are an early class, consisting of eight proteins synthesized by 6 h postinfection, an intermediate class, containing two proteins synthesized 9 h postinfection, and a late class, consisting of five proteins synthesized 12 h postinfection. In addition, there is a fourth class of polypeptides, called persistent, that are found both before and after superinfection. The rates of synthesis of the proteins fall into three patterns; these are pattern A, in which the rate of synthesis decreases, pattern B, in which the rate of synthesis remains steady, and pattern C, in which the rate of synthesis increases after the initial appearance of the polypeptide. Both 9-(2-hydroxy-ethoxymethyl)guanine (acyclovir) and phosphonoacetic acid inhibit the appearance of one intermediate protein and at least three late proteins. Seven polypeptides are phosphorylated at different times after infection.

Effect of acyclovir [9-(2-hydroxyethoxymethyl)guanine] on Epstein-Barr virus DNA replication

The effect of acyclovir [9-(2-hydroxyethoxymethyl)guanine] on Epstein-Barr virus (EBV) DNA replication in the lymphoblastoid cell lines P3HR-1 and Raji is reported. Acyclovir at a concentration of 100 microM completely inhibited EBV DNA synthesis in superinfected Raji cells, but did not inhibit DNA synthesis in mock-infected cells. The number of EBV genome equivalents per cell in the virus-producing cell line P3HR-1 was significantly reduced by acyclovir, whereas the number of latent EBV genomes in Raji cells was not affected by the drug. In situ cytohybridization performed on untreated P3HR-1 cultures revealed the presence of relatively large amounts of EBV DNA in 15 to 20% of the cells. After a 100 microM drug treatment, no P3HR-1 cells contained levels of EBV DNA detectable by in situ cytohybridization. Indirect immunofluorescence studies demonstrated that during treatment with 100 microM acyclovir for 7 days, the percentage of P3HR-1 cells expressing viral capsid antigen was reduced. The EBV DNA remaining in P3HR-1 cells after treatment with 100 microM acyclovir (approximately 14 genomes per cell) had the properties of covalently closed circular DNA with an average molecular weight of 108 X 10(6), as determined by contour length measurements.

Abortive expression of the Epstein-Barr virus (EBV) cycle in a variety of EBV DNA-containing cell lines, as reflected by nucleic acid hybridization in situ

A variety of Epstein-Barr virus (EBV) DNA-containing cell lines have been tested for the expression of the EBV-associated antigens EBNA (nuclear antigen), EA (early antigen), and VCA (viral capsid antigen), and for the presence of cells containing disproportionate amounts of EBV DNA. The antigen tests utilized immunofluorescence and 125I-labelled antibodies combined with autoradiography. EBV-DNA was detected by in situ hybridization with 3H-labelled EBV RNA complementary to P3HR-1 EBV DNA (P-EBVcRNA). The P-EBVcRNA has been shown to represent the majority of the P3HR-1 EBV DNA sequences. It was concluded that EBV DNA-containing cell lines can be divided into those that express only EBNA, those that express EBNA and EA and those that express EBNA, EA and VCA and also contain cells that undergo disproportionate EBV DNA synthesis. Consequently, in some cell lines there is an abortive expression of the EBV cycle in that some cells spontaneously express EA but fail to continue further to viral DNA synthesis. A similar pattern can be found after experimental induction of the EBV cycle, suggesting that related mechanisms govern the spontaneous expression of the EBV cycle and the extent of its inducibility.

Deoxyribonuclease activity found in Epstein--Barr virus producing lymphoblastoid cells

A deoxyribonuclease activity from Epstein--Barr (EB) virus producer lymphocyte cell lines which is correlated with viral production and which is not present in virus non-producer or negative lymphocyte cell lines has been purified 220-fold with 20% recovery and characterized. This nuclease copurifies through diethylaminoethylcellulose column chromatography with the EB virus induced deoxyribonucleic acid (DNA) polymerase in EB virus producer cells which was recently reported by this laboratory, but elutes as a separate peak of activity upon phosphocellulose chromatography. This nuclease activity has a sedimentation coefficient of 4.0 S, a strong divalent cation requirement, an alkaline pH optimum, and the ability to utilize both native and denatured lymphocyte DNA as substrate, reducing both to monophosphonucleosides.