Inducible permissive cells transformed by a temperature-sensitive polyoma virus: superinfection does not allow excision of the resident viral genome.

After exposure of mouse embryo cells to the early temperature-sensitive mutant tsP155 of polyoma virus (Py), a transformed cell line (Cyp line) that can be readily induced to synthesize Py by transfer to 33 degrees C was isolated at 39 degrees C (7). Virus production and synthesis of free viral DNA occurring after temperature shiftdown or superinfection with wild-type Py or both were studied in several clonal isolates of the Cyp cell line. Measurements of virus yields indicated that, although some could be induced more effectively than others, all cell clones behaved as highly permissive when subjected to superinfection. We analyzed the origin of free viral DNA accumulating in the superinfected cultures, taking advantage of (i) the unique physical properties of the low-molecular-weight DNA which, in the case of one of the Cyp clones, accumulates during temperature shiftdown, and (ii) the differences between resident and superinfecting viral genomes in their susceptibilities towards restriction endonucleases. At 33 degrees C, both viral genomes were found to accumulate in all clones studied whereas in the case of the clones with lower inducibility, the replication of the resident genome appeared to be enhanced by superinfection. At 39 degrees C, however, accumulation of the superinfecting genome was not accompanied by that of the resident genome, unless it had already been initiated before superinfection. These findings demonstrate that, when routinely cultivated at 39 degrees C, Cyp cells contain few viral DNA molecules readily available for autonomous replication and that, upon transfer to 33 degrees C, therefore, excision must first take place before the resident genome can accumulate as free viral DNA. Our findings also suggest that, unlike the P155 gene product provided by the resident viral genome upon induction, the allelic gene product supplied by the superinfecting genome may be less effective in triggering excision than in promoting replication.     

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.     

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.     

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.     

Amplification and excision of integrated polyoma DNA sequences require a functional origin of replication

Cells transformed by Polyoma virus (Py) can undergo a high rate of excision or amplification of integrated viral DNA sequences, and these phenomena require the presence of homology (i.e., repeats) within the viral insertion as well as a functional viral large T antigen (T-Ag). To determine whether the main role of large T-Ag in excision and amplification was replicative or recombination-promoting, we studied transformed rat cell lines containing tandem insertions of a ts-a Py molecule (encoding a thermolabile large T-Ag) with a deletion of the origin of viral DNA replication. Culturing of these cells at the temperature permissive for large T-Ag function did not result in any detectable excision or amplification of integrated Py sequences. We then introduced into origin-defective lines a recombinant plasmid containing the viral origin of replication and the gene coding for resistance to the antibiotic G418. All G418-resistant clones analyzed readily amplified the integrated plasmid molecules when grown under conditions permissive for large T-Ag function, showing that these cells produced viral large T-Ag capable of promoting amplification in trans of DNA sequences containing the Py origin. These observations strongly suggest that Polyoma large T antigen promotes excision or amplification of viral DNA by initiating replication at the integrated origin, providing a favorable substrate for subsequent recombination.     

Integration and excision of SV40 DNA from the chromosome of a transformed cell

The single insertion of SV40 DNA present in the genome of the 14B line of transformed rat cells has been cloned in procaryotic vectors. Analysis of the clones reveals a complex arrangement of viral sequences in which a small tract of DNA is inverted with respect to the major insertion. The nucleotide sequences at the two junctions show sharp transitions between cellular and viral sequences. The sequences which flank the viral insertion have been used as probes to clone the corresponding genomic sequences from the DNA of untransformed rat cells. Analysis of the structure of these clones shows that a rearrangement of cellular sequences has occurred, presumably as a consequence of integration. When 14B cells are fused with uninfected simian cells a heterogeneous set of low molecular weight superhelical DNAs containing viral sequences is generated. These have been cloned in procaryotic vectors and their structures have been analyzed. All of them span the origin of SV40 DNA replication and are colinear with various segments of the integrated viral DNA and its flanking sequences. The shorter molecules contain part of the integrated viral genome and cellular sequences from one side of the insertion. They were therefore generated by recombination between the viral DNA and its flanking cellular sequences. The longer molecules contain cellular sequences from both sides of the insertion as well as an entire copy of the integrated viral DNA. They were therefore generated by recombination between the flanking cellular sequences. These results argue strongly against the involvement of specific excision enzymes, and rather are discussed in terms of a model involving replication of the integrated viral DNA followed by recombination for release of integrated viral sequences.     

State of the viral DNA in rat cells transformed by polyoma virus. I. Virus rescue and the presence of nonintergrated viral DNA molecules.

The interaction of polyoma virus with a continuous line of rat cells was studied. Infection of these cells with polyoma did not cause virus multiplication but induced transformation. Transformed cells did not produce infectious virus, but in all clones tested virus was rescuable upon fusion with permissive mouse cells. Transformed rat cells contained, in addition to integrated viral genomes, 20 to 50 copies of nonintegrated viral DNA equivalents per cell (average). "Free" viral DNA molecules were also found in cells transformed by the ts-a and ts-8 polyoma mutants and kept at 33 C. This was not due to a virus carrier state, since the number of nonintegrated viral DNA molecules was found to be unchanged when cells were grown in the presence of antipolyoma serum. Recloning of the transformed cell lines produced subclones, which also contained free viral DNA. Most of these molecules were supercoiled and were found in the muclei of the transformed cells. The nonintegrated viral DNA is infectious. Its specifici infectivity is, however, about 100-fold lower than that of polyoma DNA extracted from productively infected cells, suggesting that these molecules contain a large proportion of defectives.     

Unintegrated viral sequences in rat cells transformed by simian virus 40 and a temperature sensitive A gene mutant

The status of viral sequences in rat cells transformed by simian virus 40 (SV40) and its temperature sensitive A gene mutant was investigated. Agarose gel electrophoresis of cell DNA prepared from clones picked from soft-agar and blot hybridization showed that sequences specific to SV40 genome were present both as integrated and unintegrated structures in rat clones. Digestion of rat cell DNA with various endonucleases with or without recognition sites in SV40 DNA and analysis indicated that the unintegrated viral genomes existed as full-length, covalently closed circular molecules. No differences in the free viral genomes were apparent between the clones transformed by the wild type and the mutant virus. The importance of the existence of free viral genomes in nonpermissive cells is discussed.     

Site-specific excision of integrated polyoma DNA

Cyp cells are permissive murine cells carrying a thermosensitive polyoma virus genome that remains integrated at 39 degrees C, but is effectively excised and replicated after transfer to 33 degrees C. In rare subclones of the Cyp line, temperature shift-down yields predominantly homogeneous populations of chimeric molecules that appear to reflect the circularization of defined segments of DNA spanning one of the junctions between the integrated viral genome and the adjacent cellular DNA. Such accurate and frequent excision requires a specific recombination mechanism. We examined both the cellular and the viral sequences that cross-over to generate one of these chimeric molecules, Rm I. The homology at the cross-over site is one of 1 or 2 base pairs at most; patches of homology, amounting in total to 19 or 20 base pairs, are found in perfect register on both sides of this site; and the two stretches of DNA that are joined to form RM I contain similar 12-14 base pair sequences (5'- CTCCTTTACAGAGG -3' and 5'- CTCCTTTCAAGG -3') in opposite orientations.     

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.     

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.     

Titration of integrated simian virus 40 DNA sequences, using highly radioactive, single-stranded DNA probes.

Nick-translated simian virus 40 (SV40) [32P]DNA fragments (greater than 2 X 10(8) cpm/micrograms) were resolved into early- and late-strand nucleic acid sequences by hybridization with asymmetric SV40 complementary RNA. Both single-stranded DNA fractions contained less than 0.5% self-complementary sequences; both included [32P]-DNA sequences that derived from all regions of the SV40 genome. In contrast to asymmetric SV40 complementary RNA, both single-stranded [32P]DNAs annealed to viral [3H]DNA at a rate characteristic of SV40 DNA reassociation. Kinetics of reassociation between the single-stranded [32P]DNAs indicated that the two fractions contain greater than 90% of the total nucleotide sequences comprising the SV40 genome. These preparations were used as hybridization probes to detect small amounts of viral DNA integrated into the chromosomes of Chinese hamster cells transformed by SV40. Under the conditions used for hybridization titrations in solution (i.e., 10- to 50-fold excess of radioactive probe), as little as 1 pg of integrated SV40 DNA sequence was assayed quantitatively. Among the transformed cells analyzed, three clones contained approximately one viral genome equivalent of SV40 DNA per diploid cell DNA complement; three other clones contained between 1.2 and 1.6 viral genome equivalents of SV40 DNA; and one clone contained somewhat more than two viral genome equivalents of SV40 DNA. Preliminary restriction endonuclease maps of the integrated SV40 DNAs indicated that four clones contained viral DNA sequences located at a single, clone-specific chromosomal site. In three clones, the SV40 DNA sequences were located at two distinct chromosomal sites.     

BK virus-transformed inbred hamster brain cells: status of viral DNA in subclones.

We have recently reported that viral DNA sequences in inbred LSH hamster brain cells transformed by the GS variant of BK virus (LSH-BR-BK) are present predominantly in a free form (Beth et al., J. Virol. 40:276-284, 1981). In this report, we confirm that the presence of viral DNA sequences in these cells is not due to virus production, since viral capsid proteins were not detected by immunoprecipitation. Furthermore, we examined the status of viral DNA in 15 subclones of this cell line and detected free and integrated viral DNA sequences in only 5 of the subclones. The other 10 subclones contained exclusively integrated viral DNA sequences, as shown by the blot hybridization of high-molecular-weight cell DNA which was uncleaved or digested with HincII, for which there are no sites in viral DNA. The arrangement of viral DNA in these clones was further analyzed by cleavage of cellular DNA with HpaII and HindIII. Mitomycin (0.03 microgram/ml) treatment of subclones containing only integrated sequences resulted in the appearance of free viral DNA sequences in some of these cells. This result supports the postulation that free viral DNA in LSH-BR-BK cells is made up of excision products of observed tandemly repeated integrated sequences. In addition to the large T- and small t-antigens, LSH-BR-BK and all of its 15 subclones contained two antigen species which were larger than large T and one species which was smaller than small t. The number of tumor antigens in the LSH- BR-BK cell line and its subclones with a large copy number in a free form was not more than in the subclones with low copy number and integrated DNA. This suggests that free viral DNA is not a template for tumor antigen production in transformed cells.     

Resolution and characterization of intracytoplasmic forms of reverse transcriptase from Rauscher leukemia virus-producing cells.

We have investigated the association of viral DNA with cell DNA in chicken embryo kidney (CEK) cells productively infected with chicken embryo lethal orphan (CELO) virus and in human (HEK) cells infected with mutants ts36 and ts125 of human adenovirus type 5 under permissive and restrictive conditions. Cell and viral DNA molecules were separated after CELO virus infection of CEK cells by alkaline sucrose gradient centrifugation, network formation, and CsCl density gradient centrifugation, methods that rely on different properties of the DNA. The cell DNA was then tested for viral sequences by DNA reannealing kinetics. Between 500 and 1,000 viral genome equivalents per cell were found at 36 h postinfection associated with cell DNA purified by each method. These values greatly exceeded the amount of free viral DNA found contaminating cell DNA prepared by the same methods from uninfected cells to which CELO virus DNA had been added. Quantitative agreement in the amounts of viral DNA found associated with cell DNA purified by these different methods suggests that CELO virus DNA is integrated into chick cell DNA during lytic infection. Similar experiments in HEK cells using mutants ts36 and ts125 of adenovirus type 5 at both restrictive and permissive temperatures showed that the same proportion of viral DNA is associated with cell DNA in the absence of viral DNA replication, and this suggests that the difference in the frequency with which cells are transformed by these mutants is not due to a difference in the frequency integration.     

Spontaneous rearrangement of integrated simian virus 40 DNA in nine transformed rodent cell lines.

Frequencies of spontaneous DNA rearrangement within or near integrated simian virus 40 (SV40) DNA were measured in four transformed mouse and rat cell lines of independent origin and in five clones of the SV40-transformed mouse line SVT2. Rearrangements were detected as polymorphisms of restriction enzyme fragment length in subclones of the lines. At least 17% of the subclones of each line had detectable rearrangements. The rate of rearrangement was calculated to be at least 5 x 10(-3) events per cell per division. No rearrangements were detected in sequences of an immunoglobulin gene, part of the coding region of the mouse protein p53, and five proto-oncogenes. The possible role of recombination between duplicated segments of integrated SV40 DNA in generating rearrangements was studied in the five SVT2 clones, which differed in the number of duplications within a single SV40 DNA segment. The SVT2 clone that had no duplications, M3, became rearranged further at least as frequently as did closely related lines with one, two, or three duplications. Another line in this group that had one small duplication, X1, had a much higher frequency of rearrangement than did the others; integrated SV40 DNA of X1 became mostly rearranged within 100 cell divisions. The examples of M3 and X1 suggested that the high rate of rearrangement characteristic of integrated SV40 DNA was influenced more by the presence of particular sequences within or near integrated SV40 DNA than by the number or extent of duplicated sequences.     

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.     

Transformation with specific fragments of adenovirus DNAs. II. Analysis of the viral DNA sequences present in cells transformed with a 7% fragment of adenovirus 5 DNA

Five clones of rat kidney cells transformed by a small restriction endonuclease fragment of adenovirus 5 (Ad5) DNA (fragment HsuI G, which represents the left terminal 7% of the adenovirus genome) were analyzed with respect to the viral DNA sequences present in the cellular DNAs. In these analyses, the kinetics of renaturation of 32P-labeled specific fragments of Ad5 DNA was measured in the presence of a large amount of DNA extracted either from each of the transformed cell lines or from untransformed cells. The fragments were produced by digestion of 32P-labeled adenovirus 5 DNA with endo R.HsuI, or by digestion of 32P-labeled fragment HsuI G of adeno 5 DNA with endo R.HpaI. All five transformed lines were found to contain DNA sequences homologous to 75--80% of Ad5 fragment HsuI G only. Clones II and V contained approximately 48 copies per quantity of diploid cell DNA, clone VI about 35 copies, clone IV 22 copies and clone III 5--10 copies. These results indicate that a viral DNA segment as small as 5.5% of the Ad5 genome, contains sufficient information for the maintenance of transformation.     

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.     

Integration of Rous sarcoma virus DNA during transfection

We have investigated the organization and integration sites of Rous sarcoma virus (RSV) DNA in NIH 3T3 mouse cells transformed by transfection with unintegrated and integrated donor RSV DNAs. RSV DNAs of different cell lines transformed by unintegrated donor DNA were flanked by different cellular DNA sequences, indicating that RSV DNA integrates at multiple sites during transfection. The RSV genomes of cells transformed by transfection were colinear with unintegrated RSV DNA, except that deletions within the terminal repeat units of RSV DNA were detected in some cell lines. These results suggested that the terminal repeat sequences of RSV DNA did not necessarily provide a specific integration site for viral DNA during transfection. In addition, cell lines transformed by integrated RSV DNAs contained both the RSV genomes and flanking cellular sequences of the parental cell lines, indicating that integration of integrated viral DNA during transfection occurred by recombinational events within flanking cellular DNA sequences rather than at the terminal of viral DNA. Integration of RSV DNA during transfection thus appears to differ from integration of RSV DNA in virus-infected cells, where the terminal repeat units of viral DNA provide a highly specific integration site. Integration of donor DNA during transfection of NIH 3T3 cells instead appears to proceed by a pathway which is nonspecific for both donor and recipient DNA sequences.     

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.