Molecular cloning of the complete Epstein-Barr virus genome as a set of overlapping restriction endonuclease fragments.

A complete collection of fragments of Epstein-Barr virus DNA, obtained by cleavage with restriction endonuclease Eco RI, has been cloned. Fourteen different internal fragments of the virus genome, derived from linear virion DNA of the B95-8 strain, and sequences corresponding to the terminal regions of virion DNA, derived from intracellular circular EBV DNA isolated from 895-8 cells, were cloned. Sizes of fragments were determined by agarose gel electrophoresis and their sum leads to an estimated molecular weight of 110 x 10(6) for virion DNA. Large Eco RI DNA fragments of special interest were also cloned in cosmids using another source of EBV DNA, that is, to circular viral DNA derived from Raji cells. In order to provide a set of overlapping sequences, all the 29 internal Bam HI fragments of B95-8 virion DNA were cloned in pBR322. The map location within the viral genome of each cloned DNA fragment was identified by hybridizing to blots of virion DNA cleaved with several different restriction endonucleases.     

Structure and role of the terminal repeats of Epstein-Barr virus in processing and packaging of virion DNA.

The linear virion Epstein-Barr virus (EBV) DNA is terminated at both ends by a variable number of direct, tandemly arranged terminal repeats (TRs) which are approximately 500 bp in size The number of TRs at each terminus can vary. After infection of host cells, the EBV DNA circularizes via the TRs by an unknown mechanism, and replication of the viral DNA during the lytic phase of the EBV life cycle leads to large DNA concatemers which need to be cleaved into virion DNA units, eventually. This cleavage event occurs at an unknown locus within the TRs of EBV, which are the cis-acting elements essential for cleavage of the concatemers and encapsidation of the virion DNA. To investigate the mechanism of DNA processing during genome circularization and cleavage of concatemeric DNA, the genomic termini of EBV were cloned, sequenced, and analyzed by direct labeling of the virion DNA. Both termini ended with identical 11-bp elements; the right end has acquired an additional 9-bp stretch that seemed to originate from the leftmost unique sequences. The left terminus is blunt, whereas the right terminus appears to have a 3' single-base extension. In a transient packaging assay, a single terminal repeat was found to be sufficient for encapsidation of plasmid DNA, and mutagenesis of the TR element defined a region of 159 bp, including the 11-bp element, which is essential for packaging. These results indicate that the genomic termini of EBV are not generated by a simple cut of a hypothetical terminase. The mechanism for cleavage of concatemers seems to involve recombination events.     

Linkage map of the fragments of herpesvirus papio DNA.

Herpesvirus papio (HVP), an Epstein-Barr-like virus, causes lymphoblastoid disease in baboons. The physical map of HVP DNA was constructed for the fragments produced by cleavage of HVP DNA with restriction endonucleases EcoRI, HindIII, SalI, and PvuI, which produced 12, 12, 10, and 4 fragments, respectively. The total molecular size of HVP DNA was calculated as close to 110 megadaltons. The following methods were used for construction of the map; (i) fragments near the ends of HVP DNA were identified by treating viral DNA with lambda exonuclease before restriction enzyme digestion; (ii) fragments containing nucleotide sequences in common with fragments from the second enzyme digest of HVP DNA were examined by Southern blot hybridization; and (iii) the location of some fragments was determined by isolating individual fragments from agarose gels and redigesting the isolated fragments with a second restriction enzyme. Terminal heterogeneity and internal repeats were found to be unique features of HVP DNA molecule. One to five repeats of 0.8 megadaltons were found at both terminal ends. Although the repeats of both ends shared a certain degree of homology, it was not determined whether they were identical repeats. The internal repeat sequence of HVP DNA was found in the EcoRI-C region, which extended from 8.4 to 23 megadaltons from the left end of the molecule. The average number of the repeats was calculated to be seven, and the molecular size was determined to be 1.8 megadaltons. Similar unique features have been reported in EBV DNA (D. Given and E. Kieff, J. Virol. 28:524-542, 1978).     

Concatameric replication of Epstein-Barr virus: structure of the termini in virus-producer and newly transformed cell lines.

The linear form of Epstein-Barr virus (EBV) DNA has homologous direct tandem repeats of approximately 500 bp at each terminus (TR). After infection, EBV DNA circularizes via the TR to form the intracellular episomal DNA. To analyze the mechanism of the synthesis of linear DNA through possible replicative intermediates, the terminal fragments were identified in the total intracellular DNA and the covalently closed circular DNA from a productively infected cell line after induction of replication or after treatment with an inhibitor of viral DNA synthesis. These studies indicate that some of the fused terminal fragments detected in the total intracellular DNA are replication-dependent forms which are selectively excluded from the covalently closed circular fraction and are eliminated after treatment with acyclovir. The EBV terminal restriction enzyme fragments were identified in three producer cell lines, each with a characteristic number of TR in the intracellular episomal DNA. Identification of the termini in cell lines established with the three virus strains revealed that the newly transformed cell lines had a greater number of TR than did the template DNA in the producer cell line. The increase in the number of TR in progeny episomes indicates that linear DNA is produced from concatameric replicative intermediates rather than from amplified catenated circular intermediates.     

Defective infectious particles and rare packaged genomes produced by cells carrying terminal-repeat-negative epstein-barr virus

The Epstein-Barr virus (EBV) lytic program includes lytic viral DNA replication and the production of a viral particle into which the replicated viral DNA is packaged. The terminal repeats (TRs) located at the end of the linear viral DNA have been identified as the packaging signals. A TR-negative (TR(-)) mutant therefore provides an appropriate tool to analyze the relationships between EBV DNA packaging and virus production. Here, we show that supernatants from lytically induced 293 cells carrying TR mutant EBV genomes (293/TR(-)) contain large amounts of viral particles devoid of viral DNA which are nevertheless able to bind to EBV target cells. This shows that viral DNA packaging is not a prerequisite for virion formation and egress. Rather surprisingly, supernatants from lytically induced 293/TR(-) cells also contained rare infectious viruses carrying the viral mutant DNA. This observation indicates that the TRs are important but not absolutely essential for virus encapsidation.     

Structure and composition of the adenovirus type 2 core.

The structure and composition of the core of adenovirus type 2 were analyzed by electron microscopy and biochemical techniques after differential degradation of the virion by heat, by pyridine, or by sarcosyl treatment. In negatively stained preparations purified sarcosyl cores reveal spherical subunits of 21.6-nm diameter in the electron microscope. It is suggested that these subunits are organized as an icosahedron which has its axes of symmetry coincident with those of the viral capsid. The subunits are connected by the viral DNA molecule. The sarcosyl cores contain the viral DNA and predominantly the arginine/alanine-rich core polypeptide VII. When sarcosyl cores are spread on a protein film, tightly coiled particles are observed which gradually unfold giving rise to a rosette-like pattern due to the uncoiling DNA molecule. Completely unfolded DNA molecules are circular. Pyridine cores consist of the viral DNA and polypeptides V and VII. In negatively stained preparations of pyridine cores the subunit arrangement apparent in the sarcosyl cores is masked by an additional shell which is probably formed by polypeptide V. In freeze-cleaved preparations of the adenovirion two fracture planes can be recognized. One fracture plane probably passes between the outer capsid of the virion and polypeptide V exposing a subviral particle which corresponds to the pyridine core. The second fracture plane observed could be located between polypeptide V and the polypeptide VII-DNA complex, thus uncovering a subviral structure which corresponds to the sarcosyl core. In the sarcosyl core polypeptide VII is tightly bound to the viral DNA which is susceptible to digestion with DNase. The restriction endonuclease EcoRI cleaves the viral DNA in the sarcosyl cores into the six specific fragments. These fragments can be resolved on polyacrylamide-agarose gels provided the sarcosyl cores are treated with pronase after incubation with the restriction endonuclease. When pronase digestion is omitted, a complex of the terminal EcoRI fragments adenovirus DNA and protein can be isolated. From this complex the terminal DNA fragments can be liberated after pronase treatment. The complex described is presumably responsible for the circularization of the viral DNA inside the virion. The nature of the protein(s) involved in circle formation has not yet been elucidated.     

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.     

The structure of the termini of the Epstein-Barr virus as a marker of clonal cellular proliferation

The linear virion form of Epstein-Barr virus (EBV) DNA has variable numbers of direct tandem 500 bp repeats at each terminus. The terminal restriction endonuclease fragments and the fused terminal fragments in the intracellular episomal form are heterogeneous in size, and vary by increments of 500 bp. The structure of the termini of EBV in carcinomas of the nasopharynx and the parotid gland was compared with the EBV termini in monoclonal and polyclonal tissues or cell lines. A single band representing the EBV joined termini was detected in each of the carcinomas and in the monoclonal lymphoid proliferations. Polyclonal cell lines contained multiple forms of the joined termini. The detection of a homogeneous episomal population suggests that EBV-associated epithelial malignancies are clonal expansions of a single EBV-infected progenitor cell.     

Amplification of Epstein-Barr virus (EBV) DNA by superinfection with a strain of EBV derived from nasopharyngeal carcinoma.

Epstein-Barr virus (EBV) from a nasopharyngeal carcinoma (NPC) hybrid cell line (NPC-KT) lacking defective viral DNA molecules superinfected Raji cells and induced EBV early antigens (EA), as did virus from P3HR-1 cells, which contained defective molecules. The EBV polypeptides induced by NPC-KT appeared to be identical to those induced by P3HR-1 virus. The ability of NPC-KT virus to induce EA was enhanced more than 10-fold by treatment of superinfected cells with dimethyl sulfoxide; however, dimethyl sulfoxide treatment did not enhance superinfection by P3HR-1 virus. After infection, DNA synthesis of both the superinfecting NPC-KT virus and the resident Raji viral genome was induced. In addition to amplified Raji EBV episomal DNA, a fused terminal fragment of NPC-KT viral DNA was detected. The detection of fused terminal DNA fragments suggests that the superinfecting virion DNA either circularizes or polymerizes after superinfection and is possibly amplified through circular or concatenated replicative intermediates.     

Anatomy of herpes simplex virus DNA. V. Terminally repetitive sequences.

Native DNA from four strains of herpes simplex virus 1 (HSV-1) circularized after digestion with the lambda exonuclease, indicating that the molecules were terminally repetitious. In two strains, the terminal repetition was evident in nearly 50% of the DNA molecules. Maximal circularization was observed when only 0.25 to 0.5% of the DNA was depolymerized by the exonuclease, suggesting that the minimal size of the terminally repetitious regions is in the range of 400 to 800 bases pairs. More extensive exonuclease treatment resulted in a reduction in the frequency of circularization. To determine whether the terminally repetitive regions themselves contained self-annealing sequences that were precluding circularization of more extensively digested DNA, the terminal fragments from HinIII restriction endonuclease digests were isolated, denatured, and tested for their ability to self-anneal. The results of hydroxyapatite column chromatography and electron microscope examination of the terminal regions are consistent with this hypothesis.     

Conservation and progressive methylation of Epstein-Barr viral DNA sequences in transformed cells.

The structure of intracellular viral DNA from a number of cell lines arising by clonal transformation of human lymphocytes in vitro with Epstein-Barr virus was analyzed. Intracellular viral DNAs were partially purified and digested with several restriction endonucleases, and the products of digestion were separated by electrophoresis in agarose gels. The viral fragments were detected by transferring the DNA from the gel to nitrocellulose sheets, hybridizing radiolabeled recombinant vectors carrying fragments of viral DNA to those transfers, and visualizing the hybrids by autoradiography. These analyses indicated that: (i) regions of repetitious viral DNA do undergo expansion and contraction although one size predominates; (ii) novel sequence arrangements appear in the intracellular viral DNA of different clones but are not found in clones analyzed serially and propagated extensively; (iii) the viral DNA is increasingly methylated upon cell propagation. We have not identified a transformed cell phenotype or a viral phenotype that segregates with the observed progressive methylation. We have not detected in Epstein-Barr viral plasmids analogs of the gross rearrangements of viral DNAs observed after lytic infections with high multiplicities of papova-, adeno-, or herpes simplex viruses.     

Size of the intracellular circular Epstein-Barr virus DNA molecules in infectious mononucleosis-derived human lymphoid cell lines.

The size of non-integrated circular Epstein-Barr virus (EBV) DNA molecules isolated from seven different human lymphoblastoid cell lines of infectious mononucleosis origin has been determined by sedimentation analysis and by direct contour length measurements on electron micrographs. Six lines had intracellular circular EBV genomes of the same size as linear virion DNA molecules. The seventh line, established with the B95-8 strain of EBV, was the only one found to have circular EBV DNA molecules significantly smaller than virion DNA. The data show that intracellular EBV DNA circles of reduced size do not generally occur in infectious mononucleosis-derived cell lines.     

Structure of the rat cytomegalovirus genome termini.

The lytic replication cycle of herpesviruses can be divided into the following three steps: (i) circularization, in which, after infection, the termini of the linear double-stranded viral genome are fused; (ii) replication, in which the circular DNA serves as template for DNA replication, which generates large DNA concatemers; and (iii) maturation, in which the concatemeric viral DNA is processed into unit-length genomes, which are packaged into capsids. Sequences at the termini of the linear virion DNA are thought to play a key role in both genome circularization and maturation. To investigate the mechanism of these processes in the replication of rat cytomegalovirus (RCMV), we cloned, sequenced, and characterized the genomic termini of this betaherpesvirus. Both RCMV genomic termini were found to contain a single copy of a direct terminal repeat (TR). The TR sequence is 504 bp in length, has a high GC content (76%), and is not repeated at internal sites within the RCMV genome. The TR comprises several small internal direct repeats as well as two sequences which are homologous to herpesvirus pac-1 and pac-2 sites, respectively. The organization of the RCMV TR is unique among cytomegaloviruses with respect to the position of the pac sequences: pac-1 is located near the left end of the TR, whereas pac-2 is present near the right end. Both RCMV DNA termini carry an extension of a single nucleotide at the 3' end. Since these nucleotides are complementary, circularization of the viral genome is likely to occur via a simple ligation reaction.     

Physical characterization of SCP1, a giant linear plasmid from Streptomyces coelicolor.

SCP1, coding for the methylenomycin biosynthesis genes in Streptomyces coelicolor, was shown to be a giant linear plasmid of 350 kb with a copy number of about four by analysis with pulsed-field gel electrophoresis. A detailed physical map of SCP1 was constructed by extensive digestion with six restriction endonucleases, by DNA hybridization experiments, and finally by cloning experiments. SCP1 has unusually long terminal inverted repeats of 80 kb on both ends and an insertion sequence at the end of the right terminal inverted repeat. Analysis by pulsed-field gel electrophoresis in agarose containing sodium dodecyl sulfate revealed that a protein is bound to the terminal 4.1-kb SpeI fragments derived from both ends of SCP1. Treatment with lambda exonuclease or exonuclease III and SpeI digestion also indicated that the 5' ends of SCP1 are attached to a protein.     

Anatomy of Herpes Simplex Virus DNA XII. Accumulation of Head-to-Tail Concatemers in Nuclei of Infected Cells and Their Role in the Generation of the Four Isomeric Arrangements of Viral DNA

Previous reports (H. Delius and J. B. Clements, J. Gen. Virol. 33:125-134, 1976; G. S. Hayward, R. J. Jacob, S. C. Wadsworth, and B. Roizman, Proc. Natl. Acad. Sci. U.S.A. 72:4243-4247, 1975; B. Roizman, G. S. Hayward, R. Jacob, S. W. Wadsworth, and R. W. Honess, Excerpta Med. Int. Congr. Ser. 2:188-198, 1974) have shown that herpes simplex virus DNA extracted from virions accumulating in the cytoplasm of infected cells consists of four populations of linear molecules differing in the orientation of the covalently linked large (L) and small (S) components relative to each other. Together, these four isomeric arrangements of viral DNA display four different termini and four different L-S component junctions. In the studies reported in this paper, we analyzed with restriction endonucleases the newly replicated viral DNA shortly after the onset of viral DNA synthesis, the progeny DNA accumulating in the nuclei late in infection, and rapidly sedimenting DNA present in nuclei of infected cells at 8 h after infection. In each instance the nuclear viral DNA contained a decreased concentration of all four terminal fragments and an increase in the concentration of fragments spanning the junction of L and S components relative to the concentration of other DNA fragments. The results are consistent with the hypothesis that the viral DNA accumulating in the nuclei consists of head-to-tail concatemers arising from the replication of DNA by a rolling-circle mechanism. A model is presented for generation of all four isomeric arrangements of herpes simplex virus DNA from one arrangement based on excision and repair of unit length DNA from head-to-tail concatemers and known features of the sequence arrangement of viral DNA.     

Synthesis of defective viral DNA in HeLa cells infected with adenovirus type 3.

Virus-specific DNA fragments that are shorter than the full-length viral genomes have been isolated from HeLa cells productively infected with adenovirus type 3. A number of predominant size classes could be detected by gel electrophoresis and hybridization, and the array of sizes was similar or identical to the selection in DNA purified from incomplete particles of this serotype (E. Daniell, J. Virol. 19:685-708, 1976). A large fraction of these short DNA molecules contained long inverted terminal repetitions, as did DNA molecules from incomplete particles. Restriction analysis showed that these subgenomic molecules consist of sequences from the two molecular ends of the normal genome. These results suggest that the predominance of left-hand end fragments seen in packaged incomplete DNAs results from selective packaging, whereas the predominance of certain size classes of intracellular viral DNA is a function of prepackaging events. The incomplete DNAs were generated at all times during viral DNA replication, and the yield relative to complete DNA did not seem to vary significantly with time or multiplicity of infection or when the virus was propagated on different human cell types.