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.     

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.     

Integration and expression of viral DNA in cells transformed by host range mutants of adenovirus type 5.

Group I host range (hr) mutants of adenovirus type 5 are unable to transform rat embryo or rat embryo brain cells but induce an abnormal transformation of baby rat kidney cells. We established several transformed rat kidney cell lines and characterized them with respect to the transformed phenotype and the structure of the integrated viral DNA. The hr mutant-transformed cells, unlike wild-type virus transformants, were fibroblastic rather than epithelial, failed to grow in soft agar, and were also less tumorigenic in nude mice. Studies on the structure of the integrated viral DNA sequences showed that hr-transformed cells always contained the left end of the adenovirus DNA, but the size of the integrated DNA fragment varied among different lines, and a high percentage of the lines contained the entire viral genome colinearly integrated. The patterns of integration were maintained after prolonged growth in culture and after subcloning. Attempts to rescue infectious virus from lines which contained the entire genome were unsuccessful. Using immunoprecipitation and sodium dodecyl sulfate-polyacrylamide gel electrophoresis, we analyzed the viral proteins expressed in hr-transformed cells. Results of these studies indicated that, like wild type-transformed cells, hr transformants expressed E1B proteins of molecular weight 58,000 and 19,000.     

Relationship between integrated and nonintegrated viral DNA in rat cells transformed by polyoma virus

Fischer rat fibroblasts transformed by polyoma virus contain, in addition to viral sequences integrated into the host genome, nonintegrated viral DNA molecules, whose presence is under the control of the viral A gene. To understand the mechanism of production of the "free" viral DNA, we have characterized the DNA species produced by several rat lines transformed by wild-type virus or by ts-a polyoma virus and compared them with the integrated viral sequences. Every cell line tested yielded a characteristic number of discrete species of viral DNA. The presence of defectives was a very common occurrence, and these molecules generally carried deletions mapping in the viral "late" region. The production of multiple species of free viral DNA was not due to heterogeneity of the transformed rat cell population, and its pattern did not change upon fusion with permissive mouse cells. Analysis of the integrated viral DNA sequences in the same cell lines showed, in most cases, a full head-to-tail tandem arrangement of normal-size and defective molecules. The free DNA produced by these lines faithfully reflected the integrated species. This was true also in the case of a cell line which contained a viral insertion corresponding to approximately 1.3 polyoma genomes, with each of the repeated portions of the viral DNA molecule carrying a different-size deletion. These results support the hypothesis that the free DNA derives from the integrated form through a mechanism of homologous recombination leading to excision and limited replication.     

A specific viral DNA sequence is stably integrated in herpesvirus oncogenically transformed cells

The integration patterns of viral DNA sequences in three hamster embryo cell lines independently derived by transformation with equine herpesvirus type 1 (EHV-1) have been investigated by DNA blot hybridization analyses for the restriction enzymes Eco RI, Bgl II, Xba I and Bam HI with ³²P-labeled selected DNAs from a collection of cloned EHV-1 restriction enzyme fragments as probes. These EHV-1-transformed cell lines contained subgenomic portions of the viral genome in an integrated state at multiple sites in the host genome. At least one copy of a viral DNA sequence mapping colinearly from 0.32 to 0.38 map units within the EHV-1 genome was common among these three EHV-1 transformed cell lines. The 0.32–0.38 viral DNA sequence was maintained stably even after 125 cell passages, whereas sequences from other positions in the EHV-1 genome were lost progressively during continued cell passage. The significance of the findings that these oncogenically transformed cell lines harbor a specific region of the EHV-1 genome is discussed with regard to stable maintenance of the oncogenically transformed state.     

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.     

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.     

Untransformed rat cells containing free and integrated DNA of a polyoma nontransforming (Hr-t) mutant.

The polyoma virus hr-t deletion mutant A185, when compared to wild-type (Py) virus, is at least 10⁵ fold inhibited in its transforming ability. Total cellular DNA from 50 cell lines derived from individual colonies formed after infection of Rat-1 cells with A185 virus was analyzed for the presence of viral sequences by “blot” hybridization (Southern, 1975). Viral sequences were detected in two of these cellular DNAs. One positive cell line (18–37) was studied in detail. The viral sequences present in 18–37 cells as well as the viral sequences present in virus rescued from 18–37 after fusion with permissive mouse cells were identified as A185 and not Py sequences. The A185 viral sequences in 18–37 cells were found to exist both covalently linked to host DNA sequences (integrated) and as free forms. The integrated A185 viral sequences were present in a partial head-to-tail tandem array, as has been observed for Py sequences in transformed rat cells (Birg et al., 1979). Both integrated and free forms of A185 viral sequences were retained in subclones of the parental 18–37 cell line although a simplification of the integrated viral sequence was observed. In the 18–37 cells the 100K large T antigen was synthesized but the 55K middle and 22K small T antigen species were not detected. The 18–37 cells had a normal morphology, were density-sensitive, anchorage-dependent and did not form tumors when injected into syngeneic animals. This normal phenotype of the 18–37 cells was not a result of the inability of the cells to express the transformed phenotype, since the 18–37 cells could be transformed at a high frequency upon infection with Py virus. These results show that integration of viral sequences per se or the presence of the 100K large T antigen is not sufficient for the transformed phenotype to be expressed, and strongly suggest that Py-induced transformation is mediated by the 55K middle and/or 22K small T antigens.     

Analysis of stable and unstable viral forms in SV40-infected human keratinocytes

We analyzed the state of the genomic DNA of the papovavirus SV40 in human keratinocytes as viral-infected cells gradually acquired a transformed phenotype over time. Initially, the vast majority of the viral DNA is maintained either in a full-length supercoiled form or as truncated subgenomic fragments with little evidence of integration. However, analyses of clonal populations revealed great heterogeneity and instability of the viral DNA, and we were able to isolate one clonal subpopulation in which integrated forms of the virus appeared to predominate. Similarly, uncloned populations eventually ceased production of the "free" viral DNA after several years in culture and instead came to display tandemly repeated SV40 copies at a single host integration site. Interestingly, Bg1 II digestion of host DNA generated restriction fragments containing the integrated SV40 DNA, which were of differing sizes in cultures at the 144th vs the 163rd serial passage suggesting modification or rearrangement of sequences at or near the integration site. Host sequences flanking the integrated viral DNA at the 163rd serial passage have been isolated on restriction fragments generated by Eco RI, Bam HI, and Hpa II digestion. These analyses suggest that the integrated virus is linearized near the Bg1 I site and contains a large deletion in the SV40 early region at one of the viral-host junctions.     

Integration of the adeno-associated virus genome into cellular DNA in latently infected human Detroit 6 cells.

A clone of human cells (Detroit 6) latently infected by adeno-associated virus (AAV) has been characterized with regard to the status of the viral DNA. In both early (9 to 10) and late (118) passages of the clone, AAV-DNA was recombined with host DNA, at least in some cases as a head-to-tail tandem repeat, via the terminal sequences of the viral genome. However, it was not possible to distinguish between integration into chromosomal DNA and very large plasmids (< 20 x 10(6) molecular weight) which contain both viral and cellular DNA sequences. Although evidence for some modifications of the viral sequence was obtained, most of the integrated sequences appeared to be intact. In some cases sequences of undetermined origin separated adjacent copies of the viral genome. Free copies of the AAV genome were detectable in late passage cells, but not in early passage cells. The orientation of nucleotide sequences present in the free AAV DNA from late passage cells was indistinguishable from that of virion DNA. With the notable exception, the organization of the integrated AAV sequences as determined by restriction enzyme digestion remained constant with continued passage. Digestion with SmaI, which cleaves within the palindromic region of the terminal repetition in AAV DNA, produced reproducibly different patterns when early and late passage DNAs were compared. Several models for rescue of free copies of the genome from the integrated DNA are possible, all of which involve the terminal repetition.     

Requirements for excision and amplification of integrated viral DNA molecules in polyoma virus-transformed cells

The integration of polyoma virus DNA into the genome of transformed rat cells generally takes place in a tandem head-to-tail arrangement. A functional viral large tumor antigen (T-Ag) renders this structure unstable, as manifested by free DNA production and excision or amplification of the integrated viral DNA. All of these phenomena involve the mobilization of precise genomic “units,” suggesting that they result from intramolecular homologous recombination events occurring in the repeated viral DNA sequences within the integrated structures. We studied polyoma ts-a-transformed rat cell lines, which produced large T-Ag but contained less than a single copy of integrated viral DNA. In all of these lines, reversion to a normal phenotype (indicative of excision) was extremely low and independent of the presence of a functional large T-Ag. The revertants were either phenotypic or had undergone variable rearrangements of the integrated sequences that seemed to involve flanking host DNA. In two of these cell lines (ts-a 4A and ts-a 3B), we could not detect any evidence of amplification even after 2 months of propagation under conditions permissive for large T-Ag. An amplification event was detected in a small subpopulation of the ts-a R5-1 line after 2 months of growth at 33°C. This involved a DNA fragment of 5.1 kilobases, consisting of the left portion of the viral insertion and about 2.5 kilobases of adjacent host DNA sequences. None of these lines spontaneously produced free viral DNA, but after fusion with 3T3 mouse fibroblasts, R5-1 and 4A produced a low level of heterogeneous free DNA molecules, which contained both viral and flanking host DNA. In contrast, the ts-a 9 cell line, whose viral insertion consists of a partial tandem of ~1.2 viral genomes, underwent a high rate of excision or amplification when propagated at temperatures permissive for large T-Ag function. These results indicate that the high rate of excision and amplification of integrated viral genomes observed in polyoma-transformed rat cells requires the presence of regions of homology (i.e., repeats) in the integrated viral sequences. Therefore, these events occur via homologous intramolecular recombination, which is promoted directly or indirectly by the large viral T-Ag.     

Recombinant DNA molecules comprising bovine papilloma virus type 1 DNA linked to plasmid DNA are maintained in a plasmidial state both in rodent fibroblasts and in bacterial cells.

Transformed cells obtained after transfecting FR3T3 rat fibroblasts with DNA of bovine papilloma virus type 1 ( BPV1 ) maintained only free copies of the viral genome. Transfection with BPV1 DNA inserted in a bacterial plasmid (pBR322 or pML2 ) did not produce transformants at a detectable rate, unless the viral sequences had been first excised from the plasmid. In contrast, transfer of the same plasmids by polyethylene glycol-induced fusion of bacterial protoplasts with FR3T3 rat or C127 mouse cells led to significant transformation frequencies. A total of eight cell lines were studied, three rat and five mouse transformants, obtained with various BPV1 - pML2 recombinants. In all cell lines, both BPV1 and plasmid sequences were maintained as non-integrated molecules, predominantly as oligomeric forms of the transforming DNA. In the three rat transformants and in two of the mouse lines, parts of the non-transforming viral region and some bacterial sequences were deleted. In the remaining three mouse lines, the monomeric repeat was a non-rearranged plasmid molecule which could be re-established as a plasmid in Escherichia coli after cleavage with "one-cut" restriction endonucleases and circularization of the molecule.     

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.     

Characterization of flat revertant cells isolated from simian virus 40-transformed mouse and rat cells which contain multiple copies of viral genomes.

Eight clones of flat revertants were isolated by negative selection from simian virus 40 (SV40)-transformed mouse and rat cell lines in which two and six viral genome equivalents per cell were integrated, respectively. These revertants showed either a normal cell phenotype or a phenotype intermediate between normal and transformed cells as to cellular morphology and saturation density and were unable to grow in soft agar medium. One revertant derived from SV40-transformed mouse cells was T antigen positive, whereas the other seven revertants were T antigen negative. SV40 could be rescued only from the T-antigen-positive revertant by fusion with permissive monkey cells. The susceptibility of the revertants to retransformation by wild-type SV40 was variable among these revertants. T-antigen-negative revertants from SV40-transformed mouse cells were retransformed at a frequency of 3 to 10 times higher than their grandparental untransformed cells. In contrast, T-antigen-negative revertants from SV40-transformed rat cells could not be retransformed. The arrangement of viral genomes was analyzed by digestion of cellular DNA with restriction enzymes of different specificity, followed by detection of DNA fragments containing a viral sequence and rat cells were serially arranged within the length of about 30 kilobases, with at least two intervening cellular sequences. A head-to-tail tandem array of unit length viral genomes was present in at least one insertion site in the transformed rat cells. All of the revertants had undergone a deletion(s), and only a part of the viral genome was retained in T-antigen-negative revertants. A relatively high frequency of reversion in the transformed rat cells suggests that reversion occurs by homologous recombination between the integrated viral genomes.     

Transformation of rodent cells by a cloned DNA fragment of herpes simplex virus type 2.

Transformation of rodent cells with isolated restriction endonuclease fragments of herpes simplex virus type 2 DNA identified a region of the genome located between map positions 0.58 and 0.62. These sequences were cloned into pBR322, and the recombinant plasmid was used to transform primary rat embryo cells and NIH 3T3 cells. The transformants were selected for their ability to form dense foci on a monolayer or to form colonies in semisolid medium. In contrast to the parental rat or mouse cells, cell lines transformed with the cloned herpes simplex virus type 2 fragment grow to high saturation densities, replicate in medium containing 1% serum, form colonies in dilute methylcellulose, show reduced levels of fibronectin, and are tumorigenic in nude mice and in their syngeneic hosts. Southern blot hybridizations have detected sequences homologous to the viral fragment in high-molecular-weight DNA from the transformed cell lines that are not present in DNA from normal rodents. In all cases, the plasmid DNA was present in less than one copy per cell, and the patterns of viral sequences changed with passage of the cell line in vivo.     

Rescue of silent integrated polyoma genomes suggests homologous recombination between resident and transfected DNA fragments

Two defective polyoma virus genomes, deleted in the nucleotide sequences coding the N-termini of the tumor antigens, were introduced into Fisher 3T3 rat cells by DNA-mediated gene transfer (transfection). The resulting integrated genomes were incapable of conferring a transformed phenotype to the cells. However, after transfection of these lines with small polyoma fragments overlapping the deleted sequences, transformed clones were isolated. These clones were analyzed by Southern genomic blot hybridization and by isolation in E. coli of plasmids containing viral sequences excised following fusion with mouse polyoma growth-permissive cells. In all cases at least one intact copy of the early region of the polyoma genome was found. Furthermore, restriction sites adjacent to the initial inactive insertion remained unchanged in many of the transformed lines. These results show that functional restoration of the defective polyoma early region involves homologous recombination between the deleted viral genomes integrated in the cellular DNA and the transfecting viral fragments.     

Loss of integrated viral DNA sequences in polyomatransformed cells is associated with an active viral A function.

Rat cells transformed by polyoma virus contain, in addition to integrated viral DNA, a small number of nonintegrated viral DNA molecules. The free viral DNA originates from the integrated form through a spontaneous induction of viral DNA replication in a minority of the cell population. Its presence is under the control of the viral A locus. To determine whether the induction of free viral DNA replication was accompanied by a loss of integrated viral DNA molecules in a phenomenon similar to the "curing" of lysogenic bacteria, we selected for revertants arising in the transformed rat populations and determined whether these cells had lost integrated viral genomes. We further investigated whether the viral A function was necessary for "curing" by determining the frequency of cured cells in populations of rat cells transformed by the ts-a mutant of polyoma virus following propagation at the permissive or nonpermissive temperature. A large proportion of the revertants isolated were negative or weakly positive when assayed by immunofluorescence for polyoma T antigen and were unable to produce infectious virus upon fusion with permissive mouse cells. The T antigen-negative, virus rescue-negative clones can be retransformed by superinfection and appear to have lost a considerable proportion of integrated viral DNA sequences. Restriction enzyme analysis of the integrated viral DNA sequences shows that the parental transformed lines contain tandem repeats of integrated viral molecules, and that this tandem arrangement is generally lost in the cured derivatives. While cells transformed by wild-type virus undergo "curing" with about the same frequency at 33 degrees or 39 degrees C, cells transformed by the ts-a mutant contain a much higher frequency of cured cells after propagation at 33 degrees than at 39 degrees C. Our results indicate that in polyoma-transformed rat cells, loss of integrated viral DNA can occur at a rather high rate, producing (at least in some cases) cells which have reverted partially or completely to a normal phenotype. Loss of integrated viral DNA is never total and appears to involve an excision event. The polyoma A function (large T antigen) is necessary for such excision to occur. In the absence of a functional A gene product, the association of the viral DNA with the host DNA appears to be very stable.     

Selective sites of adenovirus (foreign) DNA integration into the hamster genome: changes in integration patterns.

We investigated whether, upon the integration of multiple copies of adenovirus type 12 (Ad12) DNA into an established mammalian (hamster) genome, the pattern of foreign DNA insertion would remain stable or change with consecutive passages of cells in culture. By the injection of purified Ad12 into newborn hamsters, tumors were induced, cells from these tumors were cultivated, and five independent cell lines, HT5, H201/2, H201/3, H271, and H281, were established. These cell lines carried different copy numbers of Ad12 DNA per cell in an integrated form and differed in morphology. Cell line HT5 had been passed twice through hamsters as tumor cells and was subsequently passaged in culture. Patterns of Ad12 DNA integration were determined by restriction cleavage of the nuclear DNA with BamHI, EcoRI, HindIII, MspI, or PstI followed by Southern blot hybridization using 32P-labeled Ad12 DNA or its cloned terminal DNA fragments as hybridization probes. In this way, the off-size fragments, which represented the sites of linkage between Ad12 and cellular DNAs, were determined. At early passage levels in culture, the integration sites of Ad12 DNA in the hamster genome, as characterized by the positions of off-size fragments in agarose or polyacrylamide gel electrophoresis, were different in the five different tumor cell lines. Upon repeated passage, however, the off-size fragment patterns generated by the five restriction endonucleases became very similar in the five tumor cell lines. This surprising result indicates that under cell culture conditions, Ad12-transformed tumor cell lines that carry the foreign (Ad12) genome in selective, probably very similar sites of the cellular genome evolve.     

Herpesvirus saimiri DNA in tumor cells--deleted sequences and sequence rearrangements.

Herpesvirus saimiri DNA in continuous lymphoblastoid cell lines obtained from viral induced tumors in marmosets has been analyzed by gel electrophoresis of restricted DNA. Southern transfer to nitrocellulose filters, and hybridization to 32P-labeled viral DNA or DNA fragments. The viral DNA fragments EcoRI-G, -H, -D, and -I, KpnI-A, and BamHI-D and -E were not detected in Southern transfers of DNA from the nonproducing 1670 cell line. For each restriction endonuclease, a new fragment appeared, consistent with a 13.0-megadalton deletion of viral DNA sequences. This deletion encompassed 35 to 48 +/- 0.6 megadaltons from the left end of the unique DNA region. A sequence arrangement map is presented for the major population of H. saimiri DNA sequences in the 1670 cell line. Although H. saimiri DNA in the nonproducing 70N2 cell line can be distinguished from viral DNA in the 1670 cell line by several criteria, the same sequences were found to be deleted in the major population of viral DNA molecules. Unlike 1670 and 70N2 cells, restricted DNA from the virus-producing cell lines 77/5 and 1926 contained all of the DNA fragments present in the parental virion DNA. DNA from 1670, 70N2, and 77/5 cells contained additional viral DNA fragments that did not comigrate with any virion DNA fragments. Most of these unexplained fragments were confined to or highly enriched in partially purified circular or linear DNA fractions. DNA from tumor cells taken directly from a tumor-bearing animal contained viral DNA indistinguishable from the parental virion DNA by the assay conditions used. These results indicate that viral DNA sequence rearrangements can occur upon cultivation of tumor cells in vitro and that excision of DNA sequences from the viral genome may play a role in establishing the nonproducing state of some tumor cell lines.     

Owl monkey astrocytoma cells in culture spontaneously produce infectious JC virus which demonstrates altered biological properties.

A tumor cell suspension of an explanted JC virus (JCV)-induced owl monkey glioblastoma was inoculated intracranially into four recipient juvenile owl monkeys. Twenty-eight months following inoculation one owl monkey developed a glioblastoma, which was explanted into tissue culture. DNA from both the tumor tissue and tumor cells in culture hybridized to a JCV DNA probe by Southern analysis, indicating that free, as well as integrated, viral DNA may be present. At the time of the second culture passage, viral JCV DNA was extracted from these cells and cloned into a plasmid vector. Nucleotide sequencing of the regulatory region of the cloned DNA demonstrated homology with the prototype Mad-1 strain of JCV and revealed a 19-base-pair deletion in the second 98-base-pair tandem repeat that eliminated a second TATA box. This deletion is characteristic of the Mad-4 strain of JCV, which is highly neurooncogenic. By the third culture passage, 100% of the cells were T-antigen positive. Approximately one-third of the cells in culture hybridized to a biotinylated JCV DNA probe when in situ hybridization was used, a technique that only detects high-copy-number of replicating viral sequences. By the culture passage 5 and continuing through culture passage 14, viable JC virions could be recovered. The T protein synthesized by this virus, now termed JCV-586, differed from both the Mad-1 and Mad-4 strains in that it formed a stable complex with the cellular p53 protein in the tumor cells. Also, the JCV-586 T protein reacted to several monoclonal antibodies made to the simian virus 40 T protein that were not recognized by either the Mad-1 or Mad-4 strains.