Nucleic acid renaturation and restriction endonuclease cleavage analyses show that the DNAs of a transforming and a nontransforming strain of Epstein-Barr virus share approximately 90% of their nucleotide sequences.

Viral DNA molecules were purified from a nontransforming and a transforming strain of Epstein-Barr virus. Each viral DNA was labeled in vitro and renatured in the presence of an excess of either one or the other unlabeled viral DNA. Both viral DNAs were also digested with the Eco R1 restriction endonuclease and subsequently labeled by using avian myeloblastosis virus DNA polymerase to repair either the EcoR1 nuclease-generated single-stranded ends of the DNAs or their single-stranded ends produced by a second digestion with exonuclease III after the first EcoR1 nuclease digestion. The results of these experiments support three general conclusions: (i) the DNAs of these two strains of Epstein-Barr virus share approximately 90% of their nucleotide sequences; (ii) both viral DNA populations are reasonably homogenous; and (iii) both DNAs contain repetitions or inverted repetitions of some of their nucleotide sequences.     

A selectable marker allows investigation of a nontransforming Epstein-Barr virus mutant.

The derivation of specifically mutated Epstein-Barr virus (EBV) recombinants is dependent on strategies to identify, enumerate, and clone infected B lymphocytes. In recent experiments, EBV recombinants containing a positive selection marker were identified and cloned in B-lymphoma (BL) cells infected and then plated under selective conditions (F. Wang, A. Marchini, and E. Kieff, J. Virol. 65:1701-1709, 1991). We now use BL cells, for the first time, as hosts for assaying and cloning otherwise isogenic EBV recombinants carrying a hygromycin phosphotransferase (HYG) gene linked to either a nontransforming deletion mutant or a transforming wild-type EBV nuclear antigen 2 (EBNA-2) gene. Both types of recombinants converted BL cells to hygromycin resistance with similar efficiency, formed episomes, and usually expressed only EBNA-1. Only the wild-type EBNA-2 HYG gene EBV recombinant transformed primary B lymphocytes. This strategy of assaying virus on BL and primary B lymphocytes makes possible the direct assessment of the transforming efficiency of an EBV recombinant. The resultant infected BL cells are also useful for the characterization of the nontransforming recombinant EBV genomes. The HYG gene insertion in the BHLF1 open reading frame eliminated BHLF1 protein expression. The insertion and resulting BHLF1 mutation did not interfere with primary B-lymphocyte infection, growth transformation, induction of lytic infection, or virus production. Thus, these experiments also indicate that neither the BHLF1 open reading frame nor the HYG gene insertion critically affects B-lymphocyte infection in vitro.     

Optimal lengths for DNAs encapsidated by Epstein-Barr virus.

We measured the efficiency of DNA packaging by Epstein-Barr virus (EBV) as a function of the length of the DNA being packaged. Plasmids that contain oriP (the origin of latent EBV DNA replication), oriLyt (the origin of lytic EBV DNA replication), the viral terminal repeats (necessary for cleavage and packaging by EBV), and various lengths of bacteriophage lambda DNA were introduced into EBV-positive cells. Upon induction of the resident EBV's lytic phase, introduced plasmids replicated as concatemers and were packaged. Plasmid-derived concatemers of DNA with certain lengths were found to predominate in isolated virion particles. We measured the distribution of lengths of plasmid concatemers found within cells supporting the lytic phase of the viral life cycle and found that this distribution differed from the distribution of lengths of concatemers found in mature virion particles. This finding indicates that the DNA packaged into mature virions represents a selected subset of those present in the cell during packaging. These observations together indicate that the length of DNA affects the efficiency with which that DNA is packaged by EBV. Finally, we measured the length of the packaged B95-8 viral DNA and found it to be approximately 165 kbp, or 10 kbp shorter than the originally predicted size for B95-8 based on its sequence. Together with the results of other studies, these findings indicate that the packaging of DNAs by EBV is dependent on two imprecisely recognized elements: the viral terminal repeats and the length of the DNA being packaged by the virus.     

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.     

Colinearity between the DNAs of Epstein-Barr virus and herpesvirus papio.

Epstein Barr virus (EBV) and herpesvirus papio (HVPapio) DNAs share a common format and 40% homology. Labeled cloned fragments of EBV DNA were hybridized to blots of XbaI, EcoRI, HindIII, and SalI fragments of HVPapio DNA. EBV fragments which mapped from 2 x 10(6) to 54 x 10(6) and from 59 x 10(6) to 106 x 10(6) daltons hybridized to fragments at identical map positions in HVPapio DNA. Regions of nonhomology were demonstrated at 0 x 10(6) to 2 x 10(6), 54 x 10(6) to 59 10(6), and 106 x 10(6) to 115 x 10(6) daltons.     

Lytic,nontransforming Epstein-Barr virus (EBV) from a patient with chronic active EBV infection.

A new wild-type isolate of Epstein-Barr virus (EBV) was identified in follow-up studies of a case of chronic active EBV infection in an 8-year-old girl who had high titres of antibody to viral capsid antigen and early antigen (EA) (greater than 20 480 and 2560 respectively), persistent splenomegaly and abnormal immunologic features. More than 10 throat washings from this patient failed to transform cord blood lymphocytes (CBL), but at least 7 were able to induce EA in Raji cells. Supernatants from cultures of the lymphoblastoid cell line obtained by in-vitro infection of this patient''s leukocytes with the B95-8 strain of EBV revealed a herpesvirus particle when examined by electron microscopy. The same supernatants were unable to transform CBL but could induce EA in Raji cells upon superinfection. In 30 or more trials the patient''s lymphocytes never transformed spontaneously but did become positive for EBV nuclear antigen and EA in the first week of culture at least twice. Parallel studies performed on the father of the patient yielded similar results. This, then, is the first report documenting lytic activity associated with a wild-type EBV isolate.     

Biomolecular analysis of a defective nontransforming Epstein-Barr virus (EBV) from a patient with chronic active EBV infection.

A virus recovered from the saliva of a child with chronic active Epstein-Barr virus (EBV) infection for 8 years was shown to induce EBV early antigen (EBV-EA) in Raji cells and to be expressed into EBV-EA in fresh EBV-negative peripheral blood leukocytes. However, it did not replicate its DNA. Oropharyngeal epithelial cells scraped from recurrent mouth lesions were similarly positive for EBV-EA. DNA extracted from these cells and digested with BamHI contained a 6-kilobase-pair fragment homologous to BamHI fragment V and B1 EBV DNA probes. Furthermore, Southern blots of the BamHI and EcoRI digests of the DNA extracted from the cell lines of the patient (transformed with EBV strain B95-8) and of her mother (spontaneous) revealed, in addition to the expected BamHI G, H, H2, and B1 fragments used as probes, additional shorter ones of a presumably endogenous defective virus.     

A transforming function of the BARF1 gene encoded by Epstein-Barr virus.

We report a new rodent cell-transforming gene, presumably involved in viral replication, encoded by Epstein-Barr virus. We previously showed that the corresponding open reading frame BARF1 is transcribed before the onset of viral DNA synthesis, and translated into a 33 kd early polypeptide (p33). Here we show that recombinant plasmids containing the BARF1 induce morphological change, anchorage-independent growth and tumorigenic transformation of established mouse fibroblast lines. The BARF1-transformed cells and the tumour tissues isolated from new-born rats after injection of such transformed cell both express p33. Transforming activity was obtained from either the genomic fragment or the cDNA sequence.     

Tumor antigens induced by nontransforming mutants of polyoma virus.

We have studied the tumor (T) antigens induced by wild-type polyoma virus and several nontransforming mutants using immunoprecipitation with antisera from animals bearing polyomya-induced tumors followed by sodium dodecylsulfate (SDS)-polyacrylamide gel electrophoresis. In a variety of mouse cells, wild-type virus induces a major T antigen species with apparent molecular weight of 100,000 daltons, and four minor T antigen species with apparent molecular weights of 63,000, 56,000, 36,000 and 22,000 daltons. Hr-t mutants, which have an absolute defect in transformation, induce a normal 100,000 dalton T antigen but are altered in the minor T antigen species. Hr-t deletion mutants induce none of the minor T antigen species seen in wild-type virus. In their place, these mutants induce T antigen species with molecular weights in the range of 6,000--9,000 daltons. The size of the very small T antigen products does not correlate in any simple way with the size or location of the deletions in the viral DNA. Point hr-t mutants induce two of the four minor T antigen species; they make apparently normal amounts of the 56,000 dalton product and reduced amounts of the 22,000 dalton product, but none of the 63,000 or 36,000 dalton species. Ts-a mutants, which have a temperature-sensitive defect in the ability to induce stable transformation, and which complement hr-t mutants, induce T antigens with the same mobility as wild-type; however, the 100,000 dalton T antigen of ts-a mutants is thermolabile compared to wild-type. A double mutant virus carrying both a ts-a mutation and a deletion hr-t mutation induces a thermolabile 100,000 dalton product and none of the minor T antigen species. Cell fractionation studies with productively infected cells have been carried out to localize the T antigen species.     

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.     

Gene mapping and expression of two immunodominant Epstein-Barr virus capsid proteins.

The genomic localization of two immunodominant genes encoding two proteins of the Epstein-Barr virus capsid antigen (VCA) complex, VCA-p18 and VCA-p40, has been identified. For that purpose, lambda gt11-based cDNA libraries were constructed from HH514.c16 cells induced for virus production. The libraries were screened with a monoclonal antibody, EBV.OT41A, directed against VCA-p40 or with affinity-purified human antibodies against VCA-p18. Sequencing of the inserts of positive plaques showed that VCA-p18 and VCA-p40 are encoded within open reading frames (ORFs) BFRF3 and BdRF1, respectively. Peptide scanning analysis of the predicted protein of ORF BdRF1 resulted in defining the epitope of monoclonal antibody EBV.OT41A at the C-terminal region. The dominant VCA-p18 reactivity of human sera can be completely inhibited by preadsorption with Escherichia coli-expressed BFRF3-beta-galactosidase. Serum of a rabbit immunized with BFRF3-beta galactosidase reacts with a VCA-specific protein of 18 kDa. In addition, BFRF3-beta-galactosidase affinity-purified antibodies react with VCA-p18 of virus-producing cells (HH514.c16). Complete inhibition of viral DNA polymerase activity by phosphonoacetic acid is associated with the absence of RNAs and protein products of both ORFs, indicating that VCA-p18 and VCA-p40 are true late antigens.     

Comparison of infectious JC virus DNAs cloned from human brain.

We cloned JC virus DNA obtained directly from brain tissue of 10 cases of progressive multifocal leukoencephalopathy and compared DNAs by restriction endonuclease mapping. Before cloning, each DNA preparation was homogeneous with respect to restriction patterns, but with the cloned DNAs we found variability in three regions of the genome among DNAs from different cases. There was a region of hypervariability between 0.67 and 0.725 map units; no two DNAs were exactly alike in this region. We determined that the origin of DNA replication also was in this region at 0.69 +/- 0.02 map units. In 4 of the 10 DNAs examined there was a deletion of approximately 75 base pairs between 0.14 and 0.235 map units, the region presumed to contain the codons for the C-terminal ends of the structural protein Vpl and for T antigen. JC virus DNA from these same four cases had an additional HincII-HpaI site at 0.895 map units in the presumptive Vp3 and Vp2 coding regions. Overall, no two JC virus genomes were identical although all were from fatal central nervous system infections and were infectious in vitro. Our restriction patterns suggest that there are two subtypes of JC virus circulating in the population.     

Epstein-Barr virus-lymphoid cell interactions. III. Effect of concanavalin A and saccharides on Epstein-Barr virus penetration

To study some aspects of Epstein-Barr virus (EBV) penetration into target cells, the effect of concanavalin A (ConA) and various saccharides on virus infectivity and cell susceptibility to EBV infection was examined. ConA treatment of the target cells, EBV, or EBV-cell complexes was found to inhibit virus antigen expression. Several control experiments with alpha-d-methyl-mannoside elution of ConA, removal of nonfused EBV particles from the cell surface by trypsin treatment, and addition of ConA at different times postinfection were performed to define the site of ConA action on EBV infection. ConA appeared to have a dual action: (i) it inhibited EBV binding to virus receptors, and (ii) it blocked the penetration of receptor-bound virus into target cells at a trypsin-sensitive stage, thus indicating that ConA prevented the fusion of viral envelope with the target cell membrane. A high sucrose concentration (0.25 M), known to inhibit cell membrane movements, was also found to block EBV penetration at a trypsinsensitive stage, thus suggesting the implication of cell membrane movements and underlying activities (or both) in viral envelope fusion. Lower concentrations of various monosaccharides (0.12 M) did not influence EBV infection. Under conditions of ConA treatment that did not influence EBV infectivity and target cells susceptibility, ConA was able to mediate virus binding to EBV receptornegative cell lines, but no virus antigens were expressed in these cells. These observations reinforced the idea that the mere attachment of EBV to lymphoid cells is not sufficient to lead to infection. In light of the present and previously published data, we postulate the existence of a specific cellular mechanism that allows the penetration of EBV into the target (B) lymphocyte.     

Vertebrate DNAs contain nucleotide sequences related to the transforming gene of avian myeloblastosis virus.

Avian myeloblastosis virus contains a continuous sequence of approximately 1,000 nucleotides which may represent a gene (amv) responsible for acute myeloblastic leukemia in chickens. This sequence appears to have been acquired from chicken DNA and to be substituted for the envelope gene in the viral genome. We used hybridization probes enriched for the amv sequences and conditions that facilitate annealing of partially homologous nucleotide sequences to show that cellular sequences related to amv are present in the genomes of all vertebrates ranging from amphibians to humans but were not detected in fish, sea urchins, or Escherichia coli. In contrast to the preceding findings, nontransforming endogenous proviral nucleotide sequences closely related to the remainder of the avian myeloblastosis virus genome and to the entire myeloblastosis-associated helper virus are present only in chicken DNA. The amv-related cellular sequences appear to be highly conserved during evolution and to be contained at only one or a few locations in the genome of vertebrates. Within closely related species, they appear to share common evolutionary genetic loci. These findings and similar ones obtained with other highly oncogenic retroviruses containing a transforming gene suggest a general mechanism for acquisition of viral oncogenic sequences and an essential role for these sequences in the normal cellular state.     

Contrasting denaturation maps of Xenopus laevis and Xenopus borealis mitochondrial DNAs.

Denaturation maps of mitochondrial DNAs of Xenopus laevis and Xenopus borealis are radically different from each other. This is in striking contrast to the invariant denaturation patterns previously recognized among mtDNAs of various Drosophila species, particularly, since the two toads may be even more closely related to each other than the Drosophila species.     

Different patterns of Epstein-Barr virus gene expression and of cytotoxic T-cell recognition in B-cell lines infected with transforming (B95.8) or nontransforming (P3HR1) virus strains

Epstein-Barr virus (EBV)-negative Burkitt's lymphoma (BL) cell lines have been converted to EBV genome positivity by in vitro infection with the transforming EBV strain B95.8 and with the nontransforming mutant strain P3HR1, which has a deletion in the gene encoding the nuclear antigen EBNA2. These B95.8- and P3HR1-converted lines have been compared for their patterns of expression of EBV latent genes (i.e., those viral genes constitutively expressed in all EBV-transformed lines of normal B-cell origin) and for their recognition by EBV-specific cytotoxic T lymphocytes (CTLs), in an effort to identify which latent gene products provide target antigens for the T-cell response. B95.8-converted lines on several different EBV-negative BL-cell backgrounds all showed detectable expression of the nuclear antigens EBNA1, EBNA2, and EBNA3 and of the latent membrane protein (LMP); such converts were also clearly recognized by EBV-specific CTL preparations with restriction through selected human leukocyte antigen (HLA) class I antigens on the target cell surface. The corresponding P3HR1-converted lines (lacking an EBNA2 gene) expressed EBNA1 and EBNA3 but, surprisingly, showed no detectable LMP; furthermore, these converts were not recognized by EBV-specific CTLs. Such differences in T-cell recognition were not due to any differences in expression of the relevant HLA-restricting determinants between the two types of convert, as shown by binding of specific monoclonal antibodies and by the susceptibility of both B95.8 and P3HR1 converts to allospecific CTLs directed against these same HLA molecules. The results suggest that in the normal infectious cycle, EBNA2 may be required for subsequent expression of LMP and that both EBNA2 and LMP (but not EBNA1 or EBNA3) may provide target antigens for the EBV-specific T-cell response.     

Comparison of partial denaturation maps with the known sequence of simian virus 40 and phi X174 replicative form DNA.

Electron microscope partial denaturation maps of two viral DNAs, simian virus 40 and φX174 replicative form, have been obtained. A simple computer program has been developed to predict denaturation maps from any given DNA sequence, based on the percentage of A · T base-pairs along the molecule. Maps constructed from the SV40 DNA and φX174 replicative form DNA base sequence show a good correlation with the experimental maps. The results show that the regions of a DNA molecule that denature first are, in fact, those regions with the highest content of adenine and thymine base-pairs.     

Identification and characterization of a DNase induced by Epstein-Barr virus.

The diterpene ester promoter of mouse skin tumors, 12-O-tetradecanoyl-phorbol-13-acetate, induced a DNase activity in the Epstein-Barr virus-producer cell line P3HR-1. The elution patterns of the enzyme from DEAE-cellulose, phosphocellulose, and DNA-cellulose columns were different from virus-associated DNA polymerase activity. The partially purified activity could be neutralized to the extent of 90% by sera of patients with nasopharyngeal carcinoma. Purified immunoglobulin G from sera of nasopharyngeal carcinoma patients inhibited this enzyme and that obtained from superinfected Raji cells to the same extent. The partially purified enzyme preferred native DNA as a substrate over denatured DNA and 3'-terminally labeled activated calf thymus DNA. The activity was inhibited by high ionic strength. Phosphonoformic acid did not have any effect on this enzyme activity.