Presence of herpes simplex virus type 2 DNA in hamster cells oncogenically transformed by ultraviolet-inactivated virus.

Herpes simplex virus type 2 (HSV-2) DNA has been detected by molecular hybridization in hamster fibroblast cells oncogenically transformed by ultraviolet-irradiated virus. At early passages after cloning in soft agar, about 40% of the HSV-2 genome was present in all the transformed cell lines at one to six copies per cell. In cell lines derived from tumors induced by these cells, the same percentage of the HSV-2 genome was also found with more uniform number of copies (between two and three). Thus the presence of viral DNA seems to be necessary for the maintenance of the transformed state in these cell lines.     

Structure and genetic complexity of the genomes of herpesvirus defective-interfering particles associated with oncogenic transformation and persistent infection.

The complexity and structural organization of defective-interfering (DI) particle DNA of equine herpesvirus type 1 (EHV-1) have been elucidated by using restriction enzyme and Southern blot hybridization analyses. DI particles were generated by serial high-multiplicity passage of EHV-1 in L-M cells, and total viral DNA was extracted from virus purified from supernatants of these serial passages. EHV-1 DI particle DNA was quantitatively separated from standard (STD) DNA by several cycles of CsCl isopycnic banding in a vertical rotor. Restriction endonuclease digestion profiles of pure DI DNA were completely different from the mapped patterns observed for EHV-1 STD DNA. Digestion of pure defective DNA with restriction enzymes (Bg/II, EcoRI, and XbaI), for which there are few or no cleavage sites within the S (short) region of the EHV-1 STD genome, yielded high-molecular-weight supermolar DNA bands, suggesting that a large subgenomic repeat unit was present in defective DNA. DNA blot hybridization analysis with the Bg/II supermolar fragment of defective DNA, intact DI particle genomic DNA, and EHV-1 STD DNA restriction enzyme fragments as 32P-labeled probes indicated that the EHV-1 DI particle genome originates predominately from the STD DNA S region (0.77 to 1.00 map units) and to a lesser extent from the left terminus of the unique long (UL) region (0.00 to 0.05 map units). None of the EHV-1 DNA sequences associated to date with EHV-1 oncogenesis (0.32 to 0.38 map units; O'Callaghan et al. in B. Roizman [ed.], Herpesviruses, in press; Robinson et al., Cell 32:204-219, 1983, and Proc. Natl. Acad. Sci., U.S.A., 78:6684-6688, 1981) were detected in the DI particle DNA. The importance of these data with regard to DNA replication of DI particles and the role of DI particles in one model system of EHV-1 oncogenic transformation are discussed.     

Oncogenic transformation by by equine herpesviruses. II. Coestablishment of persistent infection and oncogenic transformation of hamster embryo cells by equine herpesvirus type 1 preparations enriched for defective interfering particles.

Infection of permissive hamster embryo cells with virus preparations enriched for defective interfering (DI) particles of equine herpesvirus type 1 (EHV-1) resulted in persistent infection and oncogenic transformation. Six cell lines, designated DI-5 to -10, exhibited biological properties (immortality, increased saturation density, growth in soft agar, etc.) inherent to transformed cells, but 2 to 18% of the total cells in these cell lines were shown to release virus as judged by electron microscope studies and infectious center assays. The released virus was shown to be standard EHV-1 and not to contain DI particles as determined by density measurements of the viral DNA in the analytical ultracentrifuge and by interference assays using the released virus. Tumorigenicity studies revealed that inoculation of these persistently infected cells into newborn LSH inbred hamsters resulted in a lethal, fulminating hepatitis, whereas inoculation into older immunocompetent hamsters (+4 weeks) led to the development of metastatic fibrous sarcomas. Tumor cell lines (DI-5T to -10T) established from these sarcomas were shown to be transplantable and virus nonproducers. Hybridization analyses of cellular DNAs from DI transformed and tumor cell lines using 32P-labeled genomic EHV-1 DNA as probes indicated that the whole virus genome was detectable in multiple copies (23 to 45) in the transformed cells and that DNA sequences representing only 43.5 to 56.6% of the virus genome were present in amounts of 2 to 4 copies per cell in the DI tumor cells. Expression of these viral DNA sequences as demonstrated by the detection of virus-neutralizing antibodies, 50% neutralizing dose titers ranging from 1:50 to 1:1,000, in the sera of animals inoculated with either the virus-producing transformed cells or the virus-nonproducing tumor cells. Further, EHV-1-specific proteins were detected in the membrane and the perinuclear region of bothDI transformed and tumor cells by indirect immunofluorescent assays using antisera against EHV-1 structural antigens, EHV-1 nonstructural antigens, or preparations of EHV-1 DI particles. The roles of DI particles in mediating persistent infection and cellular transformation are discussed.     

Patterns of integration of viral dna sequences in the genomes of adenovirus type 12-transformed hamster cells

The patterns of integration of the viral genome have been analyzed in four hamster cell lines transformed by adenovirus type 12 (Ad12). It has previously been shown that in each of the cell lines HA12/7, T637, A2497-2 and A2497-3, the viral genome persists in multiple copies, and that different parts of the viral DNA are represented non-stoichiometrically (Fanning and Doerfler, 1976). All four cell lines are oncogenic when injected into hamsters.The DNA from each of the cell lines was extracted and cleaved in different experiments with restriction endonucleases Bam HI, Bgl II, Eco RI, Hind III, Hpa II or Sma I. The DNA fragments were separated on 1% agarose slab gels and transferred to nitrocellulose filters by the Southern technique. Ad12 DNA sequences were detected by hybridization to Ad12 DNA, which was ³²P-labeled by nick translation, and by subsequent autoradiography. In some experiments, the ³²P-labeled Eco RI restriction endonuclease fragments of Ad12 DNA were used to investigate the distribution of specific segments of the viral genome in the cellular DNA.For each cell line, a distinct and specific pattern of integrated viral DNA sequences is observed for each of the restriction endonucleases used. Moreover, viral sequences complementary to the isolated Eco RI restriction endonuclease fragments are also distributed in patterns specific for each cell line. There are striking differences in integration patterns among the four different lines; there are also similarities. Because the organization of cellular genes in virus-transformed as compared to normal cells has not yet been determined, conclusions about the existence or absence of specific integration sites for adenovirus DNA appear premature. Analysis of the integration patterns of Ad12 DNA in the four hamster lines investigated reveals that some of the viral DNA molecules are fragmented prior to or during integration. Analysis with specific restriction endonuclease fragments demonstrates that the Eco RI B, D and E fragments, comprising a contiguous segment from 0.17–0.62 fractional length units of the viral DNA, remain intact during integration in a portion of the viral DNA molecules. Although each cell line carries multiple copies of Ad12 DNA, the viral DNA sequences are concentrated in a small number of distinct size classes of fragments. This finding is compatible with, but does not prove, the notion that at least a portion of the viral DNA sequences is integrated into repetitive sequences, or else that the integrated viral sequences have been amplified after integration.In the three cell lines which were tested, the integration pattern is stable over many generations, with continuous passage-twice weekly-of cells for 6–7 months. In the three cell lines which were examined, the integration pattern is identical in a number of randomly isolated clones. Hence it can be concluded that the patterns of integration are identical among all cells in a population of a given line of transformed cells.     

Arrangement of Integrated Avian Sarcoma Virus DNA Sequences Within the Cellular Genomes of Transformed and Revertant Mammalian Cells

We have examined the arrangement of integrated avian sarcoma virus (ASV) DNA sequences in several different avian sarcoma virus transformed mammalian cell lines, in independently isolated clones of avian sarcoma virus transformed rat liver cells, and in morphologically normal revertants of avian sarcoma virus transformed rat embryo cells. By using restriction endonuclease digestion, agarose gel electrophoresis, Southern blotting, and hybridization with labeled avian sarcoma virus complementary DNA probes, we have compared the restriction enzyme cleavage maps of integrated viral DNA and adjacent cellular DNA sequences in four different mouse and rat cell lines transformed with either Bratislava 77 or Schmidt-Ruppin strains of avian sarcoma virus. The results of these experiments indicated that the integrated viral DNA resided at a different site within the host cell genome in each transformed cell line. A similar analysis of several independently derived clones of Schmidt-Ruppin transformed rat liver cells also revealed that each clone contained a unique cellular site for the integration of proviral DNA. Examination of several morphologically normal revertants and spontaneous retransformants of Schmidt-Ruppin transformed rat embryo cells revealed that the internal arrangement and cellular integration site of viral DNA sequences was identical with that of the transformed parent cell line. The loss of the transformed phenotype in these revertant cell lines, therefore, does not appear to be the result of rearrangement or deletions either within the viral genome or in adjacent cellular DNA sequences. The data presented support a model for ASV proviral DNA integration in which recombination can occur at multiple sites within the mammalian cell genome. The integration and maintenance of at least one complete copy of the viral genome appear to be required for continuous expression of the transformed phenotype in mammalian cells.     

Viral DNA in transformed cells: II. A study of the sequences of adenovirus 2 DNA in nine lines of transformed rat cells using specific fragments of the viral genome

³²P-labeled adenovirus 2 DNA was treated with restricting endonuclease from Escherichia coli strain RY-13 (Yoshimori, 1972) (EcoRI) or restricting endonuclease from Hemophilus parainfluenzae (Hpa I) and the resulting fragments of DNA were separated by gel electrophoresis. The kinetics of renaturation of each of the fragments and of complete adenovirus 2 DNA were measured in the presence of DNA extracted from nine lines of adenovirus 2-transformed rat cells and from control cells. Six of the transformed cell lines contained viral DNA sequences homologous to two of the seven Hpa I⁴ fragments and to part of one of the six EcoRI fragments. From the order of the fragments formed by EcoRI and Hpa I on the adenovirus 2 map we conclude that these cell lines contain only the segment of viral DNA that stretches from the left-hand end to a point about 14% along the viral genome. Thus, any viral function expressed in transformed cells must be coded by this small section of viral DNA. The three remaining lines of adenovirus 2-transformed rat cells are more complicated and contain not only the sequences from the left-hand end of the viral DNA, but also other segments of the viral genome. However, no adenovirus 2-transformed rat cell contained DNA sequences homologous to the complete viral genome.     

Patterns of Viral DNA Integration in Cells Transformed by Wild Type or DNA-Binding Protein Mutants of Adenovirus Type 5 and Effect of Chemical Carcinogens on Integration

The integration pattern of viral DNA was studied in a number of cell lines transformed by wild-type adenovirus type 5 (Ad5 WT) and two mutants of the DNA-binding protein gene, H5ts125 and H5ts107. The effect of chemical carcinogens on the integration of viral DNA was also investigated. Liquid hybridization (C(0)t) analyses showed that rat embryo cells transformed by Ad5 WT usually contained only the left-hand end of the viral genome, whereas cell lines transformed by H5ts125 or H5ts107 at either the semipermissive (36 degrees C) or nonpermissive (39.5 degrees C) temperature often contained one to five copies of all or most of the entire adenovirus genome. The arrangement of the integrated adenovirus DNA sequences was determined by cleavage of transformed cell DNA with restriction endonucleases XbaI, EcoRI, or HindIII followed by transfer of separated fragments to nitrocellulose paper and hybridization according to the technique of E. M. Southern (J. Mol. Biol. 98: 503-517, 1975). It was found that the adenovirus genome is integrated as a linear sequence covalently linked to host cell DNA; that the viral DNA is integrated into different host DNA sequences in each cell line studied; that in cell lines that contain multiple copies of the Ad5 genome the viral DNA sequences can be integrated in a single set of host cell DNA sequences and not as concatemers; and that chemical carcinogens do not alter the extent or pattern of viral DNA integration.     

Genomic termini of equine herpesvirus 1.

After cell infection with the equine herpesvirus 1 (EHV-1), the termini of the linear double-stranded DNA genome fuse to form circular forms. To investigate the mechanisms in the generation and cleavage of such replicative-form DNAs, the genomic termini, the fusion of termini from replicative-form molecules, and the junction between the short and long genome segments have been analyzed by restriction mapping, blot hybridizations, cloning, and sequencing. The data suggest that the genome ends are not redundant and that the genomic termini are fused in replicative intermediates via 3' single-base extensions at the termini of the unique long segment (UL) and terminal repeat (TR). Adjacent to the EHV-1 termini are AT and gamma sequence elements highly conserved among different herpesviruses. We propose that both of these sequence elements are important for the cleavage of EHV-1 replicative forms.     

Comparison of viral RNA sequences in adenovirus 2-transformed and lytically infected cells

The complementary strands of fragments of ³²P-labelled adenovirus 2 DNA generated by cleavage with restriction endonucleases EcoRI or Hpa1 were separated by electrophoresis. Saturation hybridization reactions were performed between these fragment strands and unlabelled RNA extracted from the cytoplasm of adenovirus 2-transformed rat embryo cells or from human cells early after adenovirus 2 infection. The fraction of each fragment strand complementary to RNA from these sources was measured by chromatography on hydroxylapatite. Maps of the viral DNA sequences complementary to messenger RNA in different lines of transformed cells and early during lytic infection of human cells were constructed.Five lines of adenovirus 2-transformed cells were examined. All contained the same RNA sequences, complementary to about 10% of the light strand of EcoRI fragment A. DNA sequences coding for this RNA were more precisely located using Hpa1 fragments E and C and mapped at the left-hand end of the genome. Thus any viral function expressed in all adenovirus 2-transformed cells, tumour antigen, for example, must be coded by this region of the viral genome. Two lines, F17 and F18, express only these sequences; two others, 8617 and REM, also contain mRNA complementary to about 7% of the heavy strand of the right-hand end of adenovirus 2 DNA; a fifth line, T2C4, contains these and many additional viral RNA sequences in its cytoplasm.The viral RNA sequences found in all lines of transformed cells are also present in the cytoplasm of human cells during the early phase of a lytic adenovirus infection. The additional cytoplasmic sequences in the 8617 and REM cell lines also correspond to “early” RNA sequences.     

The arrangement of simian virus 40 sequences in the DNA of transformed cells.

High molecular weight DNA, isolated from eleven cloned lines of rat cells independently transformed by SV40, was cleaved with various restriction endonucleases. The DNA was fractionated by electrophoresis through agarose gels, denatured in situ, transferred directly to sheets of nitrocellulose as described by Southern (1975), and hybridized to SV40 DNA labeled in vitro to high specific activity. The location of viral sequences among the fragments of transformed cell DNA was determined by autoradiography. The DNAs of seven of the cell lines contained viral sequences in fragments of many different sizes. The remaining four cell lines each contain a single insertion of viral DNA at a different chromosomal location. The junctions between viral and cellular sequences map at different places on the viral genome.     

Adenovirus transcription. V. Quantitation of viral RNA sequences in adenovirus 2-infected and transformed cells.

The concentrations, in copies per cell, of viral RNA sequences complementary to different regions of the genome were determined at 8, 18 and 32 hours after infection of human cells with adenovirus type 2: separated strands of fragments of ³²P-labelled adenovirus 2 DNA, generated by cleavage with restriction endonucleases EcoR1, Hpa1 and BamH1, were added to reaction mixtures at sufficient concentrations to drive hybridizations with infected or transformed cell RNA. Under these conditions, the fraction of ³²P-labelled DNA entering hybrid is directly proportional to the absolute amount of complementary RNA in the reaction.At 8 hours after infection in the presence of cytosine arabinoside, “early” viral messenger RNA sequences are present at a frequency of 300 to 1000 copies per cell. The abundance of early mRNA sequences in different lines of adenovirus 2-transformed rat cells is markedly lower than their concentration in lytically infected cells. Moreover, the abundance of early mRNA in a given transformed rat cell line reflects the number of copies of its template DNA sequences per diploid quantity of cell DNA. After the onset of the late phase of the lytic cycle, the abundance of one early mRNA species, that coding for a single-stranded DNA binding protein required for viral DNA replication, is amplified. Viral RNA sequences complementary to regions of the genome coding for other early mRNA sequences remain at the level observed at 8 hours after infection.Exclusively “late” viral mRNA sequences are present over a range of concentrations, 500 to 10,000 copies per cell, depending on the region of the genome. By 18 hours after infection, the nucleus contains approximately three times as much total, viral RNA as the cytoplasm. The abundant nuclear, viral RNA sequences at 18 hours are transcribed from a contiguous region, 65% of the genome in length. In some cases, viral RNA sequences complementary to mRNA sequences are very abundant in the nucleus. When cytoplasmic and nuclear fractions are mixed and incubated under annealing conditions, some mRNA sequences will anneal with more abundant, anti-messenger nuclear RNA sequences to form double-stranded RNA. Such annealing of nuclear, viral RNA to early, cytoplasmic mRNA sequences probably accounts for the inability to detect, by filter hybridization, certain classes of early mRNA sequences during the late stage of infection.     

Transforming DNA sequences in rat cells transformed by DNA fragments of highly oncogenic human adenovirus type 12.

Rat cell lines tranformed by viral DNA fragments, EcoRI-C and HindIII-G, of adenovirus type 12 DNA were analyzed for the viral transforming DNA sequences present in cell DNAs. Cell lines transformed by the EcoRI-C fragment of adenovirus type 12 DNA (leftmost 16.5% of the viral genome) contain most of the HindIII-G sequences of the HindIII-G fragment, but at a different frequency depending on the portions of the fragment. The sequence of the AccI-H fragment of adenovirus type 12 DNA (the left part of the HindIII-G; leftmost 4.5% of the viral genome) was detected dominantly in cells transformed by the HindIII-G fragment Southern blot analysis showed that viral DNA sequences are present at multiple integration sites in high-molecular-weight cell DNA from cells transformed by the EcoRI-C or HindIII-G fragment of adenovirus type 12 DNA. These results suggest that most of the HindIII-G sequences in cells transformed by the HindIII-G fragment are present as fragmented forms.     

Nucleotide sequence analysis of the linked left and right hand terminal regions of adenovirus type 5 DNA present in the transformed rat cell line 5RK20.

A peculiar phenomenon is observed in several adenovirus type 2 or 5 (Ad2 or Ad5) transformed cell lines: the right hand and left hand terminal regions of the viral genome present in the viral DNA insertions of these cell lines are found to be linked together. A large part of the viral DNA insertion present in the Ad5 transformed rat cell line 5RK20 has been cloned in the lambda vector Charon21A, including the segment containing the linked terminal regions. Sequence analysis of the linkage region showed a perfect homology with the Ad5 DNA sequence and a direct linkage of basepair (bp) 63 of the left hand end of the viral genome to bp 108 of the right hand end. No cellular or rearranged viral sequences were present. Our findings suggest that the joining of viral sequences into the cellular genome.     

Functional mapping and DNA sequence of an equine herpesvirus 1 origin of replication.

The genome of equine herpesvirus 1 (EHV-1) defective interfering (DI) particle DNA originates from discrete regions within the standard (STD) EHV-1 genome: the left terminus (0.0 to 0.04 map units) and the inverted repeats (0.78 to 0.79 and 0.83 to 0.87 map units of the internal inverted repeat; 0.91 to 0.95 and 0.99 to 1.00 map units of the terminal inverted repeat). Since DI DNA must contain cis-acting DNA sequences, such as replication origins, which cannot be supplied in trans by the STD EHV-1 virus, regions of the EHV-1 genome shown to be in DI DNA were assayed for the presence of a viral origin of DNA replication. Specifically, STD EHV-1 DNA fragments encompassing the genomic regions present in DI particle DNA were inserted into the vector pAT153, and individual clones were tested by transfection assays for the ability to support the amplification and replication of plasmid DNA in EHV-1-infected cells. The Sma-1 subfragment of the internal inverted repeat sequence (0.83 to 0.85 map units) was shown to contain origin of replication activity. Subcloning and BAL 31 deletion analysis of the 2.35-kilobase-pair (kbp) Sma-1 fragment delineated a 200-bp fragment that contained origin activity. The origin activities of all EHV-1 clones which were positive by the transfection assay were confirmed by methylation analysis by using the methylation-sensitive restriction enzymes DpnI and MboI. DNA sequencing of the 200-bp fragment which contained an EHV-1 origin of replication indicated that this region has significant homology to previously characterized origins of replication of human herpesviruses. Furthermore, comparison of known origin sequences demonstrated that a 9-bp sequence, CGTTCGCAC, which is conserved among all origins of replication of human lytic herpesviruses and which is contained within the 18-bp region in herpes simplex virus type 1 origins shown by others to be protected by an origin-binding protein (P. Elias, M. E. O'Donnell, E. S. Mocarski, and I. R. Lehman, Proc. Natl. Acad. Sci. USA 83:6322-6326) is also conserved across species in the EHV-1 origin of replication.     

Integration and expression of several molecular forms of Rous sarcoma virus DNA used for transfection of mouse cells.

To assess the factors required for integration and expression of retroviral DNA, we have examined viral DNA, RNA, and protein in NIH/3T3 mouse cells transformed by transfection with various forms of cloned Rous sarcoma virus (RSV) DNA. Linear RSV DNA molecules, derived from circular DNA containing two long terminal repeats (LTRs) and permuted by cleavage at the SacI restriction endonuclease site in the leader sequence, were integrated near the ends of the linear molecule, with the LTRs on the 3' side of the src gene. Integration of a subgenomic RSV DNA fragment containing the viral src gene without intact LTRs also occurred near the ends of the linear molecule. Head-to-tail tandem arrays of RSV DNA species were observed in some transformed cell lines that received fully digested DNA and in all cell lines that received DNA ligated to produce oligomers before transfection. Closed circular RSV DNA, with one or two LTRs, integrated without apparent specificity within several regions of the viral genome. After transfection with SacI-permuted RSV DNA still linked to arms of the lambda bacteriophage vector DNA, bacteriophage sequences were joined to host DNA. Transformed cell lines produced by transfection with the various forms of RSV DNA produced similar levels of viral src protein, although the efficiency of successful transformation varied by at least two orders of magnitude. Analyses of viral polyadenylated RNA, together with the patterns of viral DNA in transformed cells, indicated that viral DNA can be integrated and expressed without regard to LTR sequences, with adjacent host DNA presumably supplying signals required for the promotion and processing of functional src mRNA.     

Preferential integration of the Ad5/SV40 hybrid virus at the highly recombinogenic human chromosomal site 1p36

Human fibroblasts transformed with an adenovirus-5/simian virus 40 recombinant construct (Ad5/SV40) were analyzed to determine the chromosomal site(s) of virus integration. This was firstly done by in situ hybridization using metaphase and prometaphase chromosomes and 125I-labeled Ad5 DNA. Out of seven transformed cell lines (six of clonal origin and one uncloned), six were proven to have integrated the viral genome at the short- or the long-subtelomeric regions of autosome 1, two regions known to include chromosomal modification sites induced by acute infection with Ad12. Characterization of the integration sites was carried out by restriction analysis. Transformed cell lines with the same major chromosomal integration site were found to have the viral genome inserted in restriction fragments of different size, indicating that viral integration has occurred at different sites within a relatively small chromosomal region. Molecular studies carried out on one of the transformed cell lines (H13.1) gave an independent confirmation of the viral integration at the subterminal region of autosome 1 short arm. Nucleotide sequencing at this cellular-viral junction has shown that the virus has integrated within tandemly repeated Alu-like elements and that the cellular flanking sequences have several homologies with variable number of tandem repeats core sequences. Many possible open reading frames were identified in the DNA segment adjacent to the Alu-like elements.     

Analysis of integrated avian RNA tumor virus DNA in transformed chicken, duck and quail fibroblasts.

The state of integration of avian sarcoma virus DNA in the genomes of transformed chicken, duck, and quail fibroblasts was deduced by means of restriction enzyme digestion of total cell DNA, gel electrophoresis, and subsequent analysis by the procedure of Southern. The cells used in these studies were either mass-infected cultures or clones of infected cells selected by their ability to form colonies in agar. For both mass-infected cultures and clones of cells of all three species, we found that integration occurred at a specific site on the viral genome but appeared to occur at many sites on the cell genome. At least some of the integrated viral DNA existed as intact nonpermuted species flanked by direct terminal repeats of at least 0.134 megadalton (217 base pairs). For each of 12 transformed quail clones studied, it was possible to detect, after digestion with Kpn I, unique junctions between viral and cellular DNA. That is, at our level of analysis, the integration site on the cell genome for each clone was different. However, within each of the 17 chicken and 9 duck clones of transformed cells, a heterogeneity presumably occurred during the outgrowth of the cell clone population, in that we could not readily detect identifiable cell-virus junction fragments.     

Integration pattern of hepatitis B virus DNA sequences in human hepatoma cell lines.

Four human hepatoma cell lines established from primary hepatocellular carcinomas were examined for the presence of hepatitis B virus DNA sequences. Reassociation kinetic analysis indicated that the cell lines HEp-3B 217, HEp-3B 14, HEp-3B F1, and PLC/PRF/5 contained two, one, one, and four genome equivalents per cell, respectively. Southern blot hybridization analysis demonstrated that hepatitis B virus DNA was integrated into the cellular DNAs of these cell lines. Further liquid hybridization studies with 32P-labeled HincII restriction fragments of hepatitis B virus DNA established that DNA sequences from all regions of the HBV genome were represented in the integrated viral sequences. Although the three HEp-3B cell lines were derived from the same tumor, they differed significantly in their patterns of integration of hepatitis B virus DNA, the number of copies of viral DNA per cell, and their ability to produce the virus-coded surface antigen.     

Herpes simplex virus DNA in transformed cells: sequence complexity in five hamster cell lines and one derived hamster tumor.

Analyses of the hybridization kinetics of labeled herpes simplex virus 2 (HSV-2) DNA with DNA from five hamster cell lines transformed by UV light-irradiated HSV-2 revealed the following. (i) Viral DNA sequences were detected in all five cell lines tested. (ii) None of the cell lines contained the full complement of HSV-2 DNA. (iii) The amount of viral DNA present in the cells varied in different transformed cell lines and ranged from 8 to 32% of the HSV-2 DNA genome in 1 to 3 copies/cell. (iv) Two parallel passages of the same cell line (333-2-29) differed in the amount of viral DNA they contained. We also compared the viral DNA sequences present in (i) one transformed cell line (333-8-9) propagated serially in culture for 80 passages, (ii) a tumor produced by inoculation of a newborn hamster with the 333-8-9 cells, and (iii) a cell line derived from a hamster tumor as above and propagated in culture for 32 passages. The results show that viral DNA present in the hamster tumor and in the cells derived from the tumor had a lower sequence complexity than that present in the original serially passaged 333-8-9 cell line.