DNA of Epstein-Barr Virus. II. Comparison of the Molecular Weights of Restriction Endonuclease Fragments of the DNA of Epstein-Barr Virus Strains and Identification of End Fragments of the B95-8 Strain

Incubation of the DNA of the B95-8 strain of Epstein-Barr virus [EBV (B95-8) DNA] with EcoRI, Hsu I, Sal I, or Kpn I restriction endonuclease yielded 8 to 15 fragments separable on 0.4% agarose gels and ranging in molecular weight from less than 1 to more than 30 x 10(6). Bam I and Bgl II yielded fragments smaller than 11 x 10(6). Preincubation of EBV (B95-8) DNA with lambda exonuclease resulted in a decrease in the Hsu I A and Sal I A and D fragments, indicating that these fragments are positioned near termini. The electrophoretic profiles of the fragments produced by cleavage of the DNA of the B95-8, HR-1, and Jijoye strains of EBV were each distinctive. The molecular weights of some EcoRI, Hsu I, and Sal I fragments from the DNA of the HR-1 strain of EBV [EBV (HR-1) DNA] and of EcoRI fragments of the DNA of the Jijoye strain of EBV were identical to that of fragments produced by cleavage of EBV (B95-8) DNA with the same enzyme, whereas others were unique to each strain. Some Hsu I, EcoRI, and Sal I fragments of EBV (HR-1) DNA and Kpn I fragments of EBV (B95-8) DNA were present in half-molar abundance relative to the majority of the fragments. In these instances, the sum of the molecular weights of the fragments was in excess of 10(8), the known molecular weight of EBV (HR-1) and (B95-8) DNA. The simplest interpretation of this finding is that each EBV (HR-1), and possibly also (B95-8), DNA preparation contains two populations of DNA molecules that differ in the arrangement of DNA sequences about a single point, such as has been described for herpes simplex virus DNA. Minor fragments could also be observed if there were more than one difference in primary structure of the DNAs. The data do not exclude more extensive heterogeneity in primary structure of the DNA of the HR-1 strain. However, the observation that the relative molar abundance of major and minor fragments of EBV (HR-1) DNA did not vary between preparations from cultures that had been maintained separately for several years favors the former hypothesis over the latter.     

Epstein-Barr Virus-Specific RNA III. Mapping of DNA Encoding Viral RNA in Restringent Infection

Namalwa and Raji cells, originally obtained from a Burkitt tumor biopsy, grow as continuous cell lines in vitro and contain the Epstein-Barr virus (EBV)-related nuclear antigen EBNA (B. M. Reedman and G. Klein, Int. J. Cancer 11:499-520, 1973) and RNA homologous to at least 17 and 30% of the EBV genome, respectively (S. D. Hayward and E. Kieff, J. Virol. 18:518-525, 1976; T. Orellana and E. Kieff, J. Virol. 22:321-330, 1977). The polyribosomal and polyadenylated [poly(A)+] RNA fractions of Namalwa and Raji cells are enriched for a class of viral RNA homologous to 5 to 7% of EBV DNA (Hayward and Kieff, J. Virol. 18:518-525, 1976; Orellana and Kieff, J. Virol. 22:321-330, 1977). The objective of the experiments described in this communication was to determine the location within the map of the EBV genome (D. Given and E. Kieff, J. Virol. 28:524-542, 1978) of the DNA which encodes the viral RNA in the poly(A)+ and non-polyadenylated [poly(A)-] RNA fractions of Namalwa cells. Hybridization of labeled DNA homologous to Namalwa poly(A)+ or poly(A)- RNA to blots containing EcoRI, Hsu I, or Hsu I/EcoRI double-cut fragments of EBV (B95-8) or (W91) DNA indicated that these RNAs are encoded by DNA contained primarily in the Hsu I A/EcoRI A and Hsu I B/EcoRI A fragments and, to a lesser extent, in other fragments of the EBV genome. Hybridizations of Namalwa poly(A)+ and poly(A)- RNA in solution to denatured labeled EcoRI A or B fragments, Hsu I A, B, or D fragments, and Hsu I A/EcoRI A or Bam I S fragments and of Raji polyribosomal poly(A)+ RNA to the EcoRI A fragment indicated that (i) Namalwa poly(A)+ RNA is encoded primarily by 6 x 10(5) daltons of a 2 x 10(6)-dalton segment of DNA, Bam I S, which is tandemly reiterated, approximately 10 times, in the Hsu I A/EcoRI A fragment and is encoded to a lesser extent by DNA in the Hsu I B, EcoRI B, and Hsu I D fragments. Raji polyribosomal poly(A)+ RNA is encoded by a similar fraction of the EcoRI A fragment as that which encodes Namalwa poly(A)+ RNA. (ii) The fraction of the Bam I S fragment homologous to Namalwa poly(A)- RNA is similar to the fraction homologous to Namalwa poly(A)+ RNA. However, Namalwa poly(A)- RNA is homologous to a larger fraction of the DNA in the Hsu I B, Hsu I D, and EcoRI B fragments.     

DNA of Epstein-Barr virus. VI. Mapping of the internal tandem reiteration.

Epstein-Barr virus (B95-8) DNA consists of short (10 X 10(6)) and long (87 X 10(6)) unique DNA sequences joined by 10 tandem reiterations of a 1.85 X 10(6) DNA segment. The reiterated sequence contains BamI and BglII sites separated by 4 X 10(5). The 4.5 X 10(5) and 14.0 X 10(5) segments generated by cleavage of the reiterated DNA with BamI and BglII contain sequences which hybridize to each other, suggesting that the internal tandemly reiterated sequence has a direct or inverted repeat within it. The opposite ends of the linear, nicked, double-stranded DNA molecule (R. F. Pritchett, S. D. Hayward, and E. D. Kieff, J. Virol. 15:556--569, 1975) consist of from 1 to 12 direct repeats of another 3 X 10(5) sequence (D. Given and E. Kieff, J. Virol. 28:524--542, 1978; D. Given, D. Yee, K. Griem, and E. Kieff, J. Virol. 30:852--862, 1979). There is no homology between the internal reiterated sequence and either terminus. However, part of the internal reiteration (less than 5 X 10(5) is reiterated at two separate locations in the long unique region. The internal reiterations are a source of variation within EBV (B95-8) DNA preparations. Thus, although the majority of molecules contain 10 tandem reiterations, some molecules have 9, 8, 7, 6, 5, 4, or fewer tandem reiterations. A consequence of this variability is that the KpnI A fragment and the EcoRI/Hsul A fragment consist of a family of seven or more fragments differing in the number of tandem internal reiterations. The EcoRI/HsuI A fragment of EBV (W91) DNA is approximately 6 X 10(6) smaller than the largest and dominant EcoRI/HsuI A fragment of EBV (B95-8) DNA. EBV (W91 DNA also differs from EBV (B95-8) DNA by an additional 7 X 10(6) to 8 X 10(6) of DNA in the long unique DNA region (D. Given and E. Kieff, J. Virol. 28:524--542, 1978; N. Raab-Traub, R. Pritchett, and E. Kieff, J. Virol. 27:388--398, 1978). These data suggest the possibility that the smaller number of internal reiterations in EBV (W91) DNA may be a consequence of the additional unique DNA and a restriction in the overall size of EBV DNA.     

DNA of Epstein-Barr virus. III. Identification of restriction enzyme fragments that contain DNA sequences which differ among strains of Epstein-Barr virus.

Previous kinetic and absorption hybridization experiments had demonstrated that the DNA of the B95-8 strain of Epstein-Barr virus was missing approximately 10% of the DNA sequences present in the DNA of the HR-1 strain (R.F. Pritchett, S.D. Hayward, and E. Kieff, J. Virol. 15:556-569, 1975; B. Sugder, W.C. Summers, and G. Klein, J. Virol. 18:765-775, 1976). The HR-1 strain differs from other laboratory strains, including the B95-8 and W91 strains, and from virus present in throat washings from patients with infectious mononucleosis in its inability to transform lymphocytes into lymphoblasts capable of long-term growth in culture (P. Gerber, Lancet i:1001, 1973; J. Menezes, W. Leibold, and G. Klein, Exp. Cell. Res. 92:478-484, 1975; G. Miller, D. Coope, J. Niederman, and J. Pagano, J. Virol. 18:1071-1080, 1976; G. Miller, J. Robinson, L. Heston, and M. Lipman, Proc. Natl. Acad. Sci. U.S.A. 71:4006-4010, 1974). In the experiments reported here, the restriction enzyme fragments of Epstein-Barr virus DNA which contain sequences which differ among the HR-1, B95-8, and W91 strains have been identified. The DNA of the HR-1, B95-8, and W91 strains each differed in complexity. The sequences previously shown to be missing in the B95-8 strain were contained in the EcoRI-C and -D and Hsu I-E and -N fragments of the HR-1 strain and in the EcoRI-C and Hsu I-D and -E fragments of the W91 strain. The HR-1 strain was missing DNA contained in EcoRI fragments A and J through K and Hsu I fragment B of the B95-8 strain and in the EcoRI-A and Hsu I-B fragments of the W91 strain. The relationship of these data to the linkage map of restriction enzyme fragments of the DNA of the B95-8 and W91 strains (E. Kieff, N. Raab-Traub, D. Given, W. King, A.T. Powell, R. Pritchett, and T. Dambaugh, In F. Rapp and G. de-The, ed., Oncogenesis and Herpesviruses III, in press; D. Given and E. Kieff, submitted for publication) and the possible significance of the data are discussed.     

Epstein-Barr virus RNA in Burkitt tumor tissue.

Analysis of the viral RNA in four Burkitt tumor biopsies indicates that tumor tissue contains RNA homologous to at least 3–6% of the DNA of Epstein-Barr virus (EBV). Most of these RNA species accumulate in the polyadenylated RNA fraction of Burkitt tumor tissue. Two approaches have been used to determine the location within the EBV genome of the DNA sequences which encode stable RNA in two Burkitt tumor biopsies, F and S, which contain 6–10 copies per cell of at least 80% of the EBV genome. With the first approach, ³²P-EBV DNA homologous to polyadenylated or nonpolyadenylated RNAs from the F, S or R tumors was hybridized to blots of fragments of EBV DNA. With the second approach, polyadenylated or nonpolyadenylated RNAs from the F or S tumors were hybridized to separated, labeled fragments of EBV DNA in solution. The results indicate that first, most of the viral RNA in Burkitt tumor tissue is encoded by approximately 20% of the Hsu I D fragment, 20% of the Eco RI A/Hsu I A double-cut fragment and 3% of the Hsu I B fragment of EBV DNA; second, an abundant RNA species in tumor tissue is homologous to the “additional DNA” present in the W91 and Jijoye/HR-I Burkitt tumor isolates of EBV and absent in the B95-8 virus, an isolate of EBV from outside the Burkitt endemic region; and third, there is little or no homology to other regions of the EBV genome.     

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.     

Cleavage of Epstein-Barr virus DNA by restriction endonucleases EcoRI, HindIII and BamI.

The cleavage of the DNAs of the B95-8 and P3HR-1 virus strains of Epstein-Barr virus by the restriction endonucleases EcoRI, HindIII and BamI was investigated using a new technique for quantitative evaluation of the fluorescence of ethidium stained DNA fragments separated on agarose gels. The results obtained with B95-8 DNA showed that in addition to the limited repetitions of nucleotide sequences observed in the EcoRI and HindIII cleavage patterns, the molecule contained a BamI fragment with a molecular mass of 2.0 megadaltons which was present in a total of about 11 copies and localized to a limited part of the DNA molecule. The same sequences were also present in the P3HR-1 DNA albeit in a lower molar ratio. P3HR-1 DNA yielded restriction enzyme cleavage patterns suggesting DNA sequence heterogeneity of P3HR-1 virus. No fragment was present in more than about 4 copies per molecule of P3HR-1 DNA. Comparison of the restriction enzyme cleavage patterns of P3HR-1 and B95-8 DNA revealed a high degree of structural homology emphasized by nucleic acid hybridization experiments with EBV complementary RNA synthesized in vitro.     

DNA of Epstein-Barr virus. I. Comparative studies of the DNA of Epstein-Barr virus from HR-1 and B95-8 cells: size, structure, and relatedness.

We have compared the properties of the DNA of Epstein-Barr virus (EBV) purified from HR-1 (EBV HR-1 DNA) and B95-8 (EBV B95-8 DNA) continuous lymphoblast cultures. Our data indicate that (i) the S suc of native EBV DNA relative to T4D DNA is 55S. Using the modified Burgi-Hershey relationship (5), we estimate the molecular weight of native EBV DNA is 101 (plus or minus the molecular weight of native FBV DNA by measurement of the length of 3) times 106. Estimation of the molecule relative to form II PM2 DNA yields a value of 105 (plus or minus 3) times 106. (ii) After alkali denaturation, less than 50% of EBV DNA sediments as a single band in alkaline sucrose gradients in the region expected for DNA of 50 times 406 daltons. (iii) Intact EBV HR-1 and EBV B 95-8 DNAs band at 1.718 g/cm3 and a smaller band (approximately 25% of the DNA) AT 1.720 G/CM3. (IV) EBV HR-1 DNA possesses greater than 97% of the sequences of EBV B95-8 DNA. Hybrid DNA molecules formed between (3H)EBV HR-1 DNA and EBV HR-1 DNA or EBV B95-8 DNA had identical thermal stability. EBV B95-8 DNA lacks approximately 15% of the DNA sequences of EBV HR-1 DNA. We interpret these data to mean that EBV B95-8 is derived from a parental EBV through loss of genetic complexity. This defect may be linked to the ability of EBV B95-8 to "transform" lymphocytes invitro.     

Recombination between compatible plasmids containing homologous segments requires the Bacillus subtilis recE gene product.

Plasmid pSL103 was previously constructed by cloning a Trp fragment (approximately 2.3 X 10(6) daltons) from restriction endonuclease EcoRI-digested chromosome DNA of Bacillus pumilus using the neomycin-resistance plasmid pUB110 (approximately 2.8 X 10(6) daltons) as vector and B. subtilis as transformation recipient. In the present study the EcoRI Trp fragment from pSL103 was transferred in vitro to EcoRI fragments of the Bacillus plasmid pPL576 to determine the ability of the plasmid fragments to replicate in B. subtilis. Endonuclease EcoRI digestion of pPL576 (approximately 28 X 10(6) daltons) generated three fragments having molecular weights of about 13 X 13(6) (the A fragment), 9.5 X 10(6) (B fragment, and 6.5 X 10(6) (C fragment). Trp derivatives of pPL576 fragments capable of autonomous replication in B. subtilis contained the B fragment (e.g., pSL107) or both the B and C fragments (e.g., pSL108). Accordingly, the B fragment of pPL576 contains information essential for autonomous replication. pSL107 and pSL108 are compatible with pUB110. Constructed derivatives of the compatible plasmids pPL576 and pUB110, harboring genetically distinguishable EcoRI-generated Trp fragments cloned from the DNA of a B. pumilus strain, exhibited relatively high frequency recombination for a trpC marker when the plasmid pairs were present in a recombination-proficient strain of B. subtilis. No recombination was detected when the host carried the chromosome mutation recE4. Therefore, the recE4 mutation suppresses recombination between compatible plasmids that contain homologous segments.     

Herpesvirus papio DNA is similar in organization to Epstein-Barr virus DNA.

EcoRI, HindII, SalI, nd XbaI restriction endonuclease maps of herpesvirus papio (HVPapio) DNA were derived by determining the fragment sizes and the linkage relationships between fragments generated by the different enzymes. The data indicate that HVPapio DNA has a single molecular arrangement which is similar to that of Epstein-Barr virus DNA. The size of the DNA was 110 X 10(6) to 114 X 10(6) daltons. Restriction fragments from both ends varied in the number of repeats of a 4 X 10(5)-dalton sequence, TR, and hybridized to each other. This suggests that there is an identical repeating unit, TR, at both ends of the DNA. There were usually six tandem repetitions (range, 1 to 11) of a 2 X 10(6)-dalton sequence, IR, within the DNA. IR separated the DNA into two domains of largely unique sequence complexity, a 9 X 10(6)-dalton segment, Us, and an 88 X 10(6)-dalton segment, UL. There was homology between DNA fragments which mapped at 25 X 10(6) to 29 X 10(6) to 91 X 10(6) to 95 X 10(6) daltons in UL.     

Genome of a mononucleosis Epstein-Barr virus contains DNA fragments previously regarded to be unique to Burkitt's lymphoma isolates

We wished to learn whether the genomes of strains of EMB isolated from patients with infectious mononucleosis are consistently distinguishable from those of strains from Burkitt's lymphoma. The genome of a new transforming strains (FF41) of EBV isolated from saliva of a patient with uncomplicated infectious mononucleosis was compared with the DNA of B95-8, the only other available virus from mononucleosis. It had been found previously that B95-8 has a deletion of about 8 Md in the region of the physical map represented by the Eco RI C, Hind III D, and Bam HI I fragments. The W91 and HR-1 isolates for Burkitt's lymphoma are not deleted in this region and it had been proposed that additional information was characteristic of EBV isolates from Burkitt's lymphoma. By means of restriction enzyme analysis, blot hybridization experiments and molecular cloning of FF41 DNA we demonstrate that the deletion found in B95-8 is not present in the new mononucleosis isolate. The FF41 genome contains an extra 8 Md of DNA, represented by Bam HI fragments B', W' and I', which are located in a larger Eco RI C fragment. Thus the genome of this salivary isolate contains DNA that had previously been regarded to be unique to strains from Burkitt's lymphoma. It is therefore unlikely that major insertions or deletions in the EBV genome account for differences in disease manifestation following EBV infection.     

Epstein-Barr virus RNA. VI. Viral RNA in restringently and abortively infected Raji cells.

Nuclear and polyadenylated RNA fractions of Raji cells are encoded by larger fractions of Epstein-Barr virus DNA (35 and 18%, respectively) than encode polyribosomal RNA (10%). Polyribosomal RNA is encoded by DNA mapping at 0.05 X 10(8) to 0.29 X 10(8), 0.63 X 10(8) to 0.66 X 10(8), and 1.10 X 10(8) to 0.03 X 10(8) daltons. An abundant, small (160-base), non-polyadenylated RNA encoded by EcoRI fragment J (0.05 X 10(8) to 0.07 X 10(8) daltons) is also present in the cytoplasm of Raji cells. After induction of early antigen in Raji cells, there was a substantial increase in the complexity of viral polyadenylated and polyribosomal RNAs. Thus, nuclear RNA was encoded by 40% of Epstein-Barr virus DNA, and polyadenylated and polyribosomal RNAs were encoded by at least 30% of Epstein-Barr virus DNA. Polyribosomal RNA from induced Raji cells was encoded by Epstein-Barr virus DNAs mapping at 0.05 X 10(8) to 0.29 X 10(8), 0.63 X 10(8) to 0.66 X 10(8), and 1.10 X 10(8) to 0.03 X 10(8) daltons and also by DNAs mapping within the long unique regions of Epstein-Barr virus DNA at 0.39 X 10(8) to 0.49 X 10(8), 0.51 X 10(8) to 0.59 X 10(8), 0.66 X 10(8) to 0.77 X 10(8), and 1.02 X 10(8) to 1.05 X 10(8) daltons.     

Correlated genetic and EcoRI cleavage map of Bacillus subtilis bacteriophage phi105 DNA.

The seven previously identified EcoRI cleavage fragments of phi 105 DNA were ordered with respect to their sites of origin on the phage genome by marker rescue. One fragment, H, did not carry any determinants essential for replication. This fragment was totally missing in a deletion mutant which exhibited a lysogenization-defective phenotype. There is a nonessential region on the phi 105 genome which begins in fragment B, spans fragment H, and ends in fragment F. The size of the nonessential region, as estimated by alterations observed in the fragmentation patterns of deletion mutant DNAs, is approximately 2.7 X 10(6) daltons. Two new EcoRI cleavage fragments with molecular weights of approximately 0.2 X 10(6) were detected by autoradiography of 32P-labeled DNA. These small fragments were not located on the cleavage map.     

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.     

Transfer of the Epstein-Barr virus genes coding for small RNAs to human lymphoid cells with a vector carrying a dominant selectable marker.

Epstein-Barr virus (EBV)-negative, Burkitt-like lymphoma-derived cells were transformed with a transducing vector (pSV2-gpt) containing the Escherichia coli gene coding for xanthine-guanine phosphoribosyltransferase (XGPRT) and with a derivative of PSV2-gpt that carries the genes for the EBV-associated small RNAs on the EcoRI J fragment of B95-8 EBV DNA inserted at the unique EcoRI site (pJ-gpt). Cells transformed with PSV2-gpt and pJ-gpt express the E. coli gpt gene to approximately the same extent, judged by determinations of the XGPRT activity of cell extracts. Blot hybridisation experiments with restriction endonuclease-cleaved DNA from the transformants have revealed the presence of vector DNA sequences in the cells, at least some of which are most probably integrated into high mol. wt. chromosomal DNA. Northern blot hybridisation analysis of cytoplasmic RNA from pJ-gpt-transformed cells revealed the presence of an EcoRI J DNA complementary RNA species of the same size as the EBV DNA-encoded small RNAs found in EBV-transformed cells.     

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.     

The structure of the termini of the DNA of Epstein-Barr virus.

We have studied the DNA of Epstein-Barr virus (EBV) isolated from the B95-8 strain of that virus (Miller and Lipman, 1973). When EBV DNA is partially digested with lambda-exonuclease and allowed to reanneal, up to 50% of the full-length molecules circularize. The arrangements of nucleotide sequences containing the terminal repeats identified in this circularization experiment have been determined. Those fragments of viral DNA generated by digestion with restriction endonucleases which are terminal and contain the terminal repeats have been identified by their sensitivity to digestion of full-length DNA by lambda-exonuclease and by virtue of their being partially homologous to one another. The population of DNA molecules in the B95-8 strain of EBV was found to be nonuniform. The nonuniformity results from different molecules having different numbers of a 0.37 megadalton terminal repeat at each end. About 70% of molecules have four terminal repeats at one end, while four equal classes, each comprising approximately 25% of the population, have one, two, three or four repeats at the other end. The arrangements of nucleotide sequences identified as being terminal in virion DNA were studied in the intracellular circular viral DNA of cells transformed by a single particle on EBV. All fragments produced by digestion with endonucleases and scored as being terminal in virion DNA were absent from intracellular circular DNA. An additional fragment was identified in the digests of intracellular DNA of each transformed clone. The molecular weights of the new fragments equal the sum of the molecular weights of two terminal fragments which are joined upon intracellular circularization of viral DNA.     

DNA of Epstein-Barr virus. V. Direct repeats of the ends of Epstein-Barr virus DNA.

Previous data indicated that Epstein-Barr virus DNA is terminated at both ends by direct or inverted repeats of from 1 to 12 copies of a 3 X 10(5)-dalton sequence. Thus, restriction endonuclease fragments which include either terminus vary in size by 3 X 10(5)-dalton increments (D. Given and E. Kieff, J. Virol. 28:524--542, 1978; S. D. Hayward and E. Kieff, J. Virol. 23:421--429, 1977). Furthermore, defined fragments containing either terminus hybridize to each other (Given and Kieff, J. Virol. 28:524--542, 1978). The 5' ends of the DNA are susceptible to lambda exonuclease digestion (Hayward and Kieff, J. Virol. 23:421--429, 1977). To determine whether the terminal DNA is a direct or inverted repeat, the structures formed after denaturation and reannealing of the DNA from one terminus and after annealing of lambda exonuclease-treated DNA were examined in the electron microscope. The data were as follows. (i) No inverted repeats were detected within the SalI D or EcoRI D terminal fragments of Epstein-Barr virus DNA. The absence of "hairpin- or pan-handle-like" structures in denatured and partially reannealed preparations of the SalI D or EcoRI D fragment and the absence of repetitive hairpin- or pan-handle-like structures in the free 5' tails of DNA treated with lambda exonuclease indicate that there is no inverted repeat within the 3 X 10(5)-dalton terminal reiteration. (ii) Denatured SalI D or EcoRI D fragments reanneal to form circles ranging in size from 3 X 10(5) to 2.5 X 1O(6) daltons, indicating the presence of multiple direct repeats within this terminus. (iii) Lambda exonuclease treatment of the DNA extracted from virus that had accumulated in the extracellular fluid resulted in asynchronous digestion of ends and extensive internal digestion, probably a consequence of nicks and gaps in the DNA. Most full-length molecules, after 5 min of lambda exonuclease digestion, annealed to form circles, indicating that there exists a direct repeat at both ends of the DNA. (iv) The finding of several circularized molecules with small, largely double-strand circles at the juncture of the ends indicates that the direct repeat at both ends is directly repeated within each end. Hybridization between the direct repeats at the termini is likely to be the mechanism by which Epstein-Barr virus DNA circularizes within infected cells (T. Lindahl, A. Adams, G. Bjursell, G. W. Bornkamm, C. Kaschka-Dierich, and U. Jehn, J. Mol. Biol. 102:511-530, 1976).