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.     

An inducible eukaryotic host-vector expression system: amplification of genes under the control of the polyoma late promoter in a cell line producing a thermolabile large T antigen

We have taken advantage of the inherent instability of integrated polyoma (Py) DNA sequences in the presence of a functional viral large T antigen (LT) to develop a eukaryotic host-vector system where copy number is controlled by temperature. A mouse cell line WOP32-4, that constitutively expresses a temperature sensitive (ts) LT, was transfected with plasmids containing the Py origin of DNA replication (ori) and either a neomycin-resistance gene (neo) or chloramphenicol acetyl transferase gene (cat) linked to the Py late promoter. Stable transformants were selected at 39 degrees C, the non-permissive temperature for the ts LT function. Upon shift to 33 degrees C, the resident Py sequences present in the WOP32-4 cells cannot excise due to an ori deletion. However, excision of the transfected plasmid molecules and subsequent extrachromosomal replication occur at high rates leading in some cases to the production of 1000-2000 copies per cell (average) of the plasmid. Proportional increases in either neo-specific mRNA or CAT activity were also observed. In situ hybridization for one cell line indicated that about 20% of temperature-shifted cells contained amplified plasmid DNA.     

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.     

The genomic instability associated with integrated simian virus 40 DNA is dependent on the origin of replication and early control region.

DNA rearrangements in the form of deletions and duplications are found within and near integrated simian virus 40 (SV40) DNA in nonpermissive cell lines. We have found that rearrangements also occur frequently with integrated pSV2neo plasmid DNA. pSV2neo contains the entire SV40 control region, including the origin of replication, both promoters, and the enhancer sequences. Linearized plasmid DNA was electroporated into X1, an SV40-transformed mouse cell line that expresses SV40 large T antigen (T Ag) and shows very frequent rearrangements at the SV40 locus, and into LMtk-, a spontaneously transformed mouse cell line that contains no SV40 DNA. Stability was analyzed by subcloning G-418-resistant clones and examining specific DNA fragments for alterations in size. Five independent X1 clones containing pSV2neo DNA were unstable at both the neo locus and the T Ag locus. By contrast, four X1 clones containing mutants of pSV2neo with small deletions in the SV40 core origin and three X1 clones containing a different neo plasmid lacking SV40 sequences were stable at the neo locus, although they were still unstable at the T Ag locus. Surprisingly, five independent LMtk- clones containing pSV2neo DNA were unstable at the neo locus. LMtk- clones containing origin deletion mutants were more stable but were not as stable as the X1 clones containing the same plasmid DNA. We conclude that the SV40 origin of replication and early control region are sufficient viral components for the genomic instability at sites of SV40 integration and that SV40 T Ag is not required.     

State of the viral DNA in rat cells transformed by polyma virus. II. Identification of the cells containing nonintegrated viral DNA and the effect of viral mutations.

F2408 rat cells transformed by polyoma virus contained integrated and nonintegrated viral DNA. The presence of nonintegrated viral DNA is under control of the A early viral function. Polyoma ts-a-transformed rat cells lose the free viral DNA when growth at the nonpermissive temperature (40 degrees C), but they reexpress it 1 to 3 days after they are shifted back to the permissive temperature. In contrast, rat cells transformed by a late viral mutant, ts-8, contain free viral DNA at both permissive and nonpermissive temperatures. Treatment of the transformed rat cells with mitomycin C produces a large increase in the quantity of free viral DNA and some production of infectious virus. Experiments of in situ hybridization, with 3H-labeled polyoma complementary RNA as a probe, show that only a minority (approximately 0.1%) of the transformed cells contain nonintegrated viral DNA at any given time. These results suggest that the presence of free viral DNA in polyoma-transformed rat cells is caused by a spontaneous induction of viral DNA replication, occurring with low but constant probability in the transformed cell population, and that the free viral DNA molecules originate from the integrated ones, probably through a phenomenon of excision and limited replication.     

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.     

Overproduction of Rb protein after the G1/S boundary causes G2 arrest.

The Rb protein is known to exert its activity at decision points in the G1 phase of the cell cycle. To investigate whether it may also play some role(s) at later points in the cell cycle, we used a system of rapid inducible gene amplification to conditionally overexpress Rb protein during G2 phase. A cell line expressing a temperature-sensitive simian virus 40 large T antigen (T-Ag) was stably transfected with plasmids containing the Rb cDNA linked to the simian virus 40 origin of replication: pRB-wt, pRB-fs, and pRB-Dra, carrying wild-type murine Rb cDNA, a frameshift mutation close to the beginning of the Rb coding region, and a single-amino-acid deletion in the E1A/T-Ag binding pocket, respectively. Numerous independent cell lines were isolated at the nonpermissive temperature; cell lines displaying a high level of episomal amplification of an intact Rb expression cassette following shiftdown to the permissive temperature were chosen for further analysis. Plasmid pRB-fs did not express detectable Rb antigen, while pRB-Dra expressed full-length Rb protein. The Dra mutation has previously been shown to abrogate phosphorylation as well as T-Ag binding. Fluorescence-activated cell sorting (FACS) analysis revealed that cultures induced to overexpress either wild-type or Dra mutant Rb proteins were significantly enriched for cells with a G2 DNA content. Cultures that amplified pRB-fs or rearranged pRB-wt and did not express Rb protein had normal cell cycle profiles. Double-label FACS analysis showed that cells overexpressing Rb or Rb-Dra proteins were uniformly accumulating in G2, whereas cells expressing endogenous levels of Rb were found throughout the cell cycle. These results indicate that Rb protein is interacting with some component(s) of the cell cycle-regulatory machinery during G2 phase.     

Integrated polyoma genomes in inducible permissive transformed cells.

Using the approach described by Botchan, Topp, and Sambrook (Cell 9:269-287, 1976), we analyzed the organization of the integrated viral sequences in five clonal isolates from the same permissive, inducible cell line (Cyp line) transformed by the tsP155 mutant of polyoma virus. In all five clones, viral sequences were found that could be assigned to a common integration site, as they were joined to the cellular DNA in the same fashion in every instance. However, the sequences comprised between these points differed markedly from clone to clone, as if cell propagation had been accompanied by amplification or recombination or both within the viral insertion. When the clones were compared, no correlation could be found between the abundance, or the organization, of the integrated viral sequences and the amount, or the nature, of the free viral DNA molecules produced during induction. Altogether, our findings suggest that specific events, occurring during either the excision or the subsequent replication of the integrated viral sequences, are responsible for the predominant production of nondefective viral DNA molecules by permissive transformed cells, such as Cyp cells.     

Requirements for species-specific papovavirus DNA replication.

Replication of papovavirus DNA requires a functional replication origin, a virus-encoded protein, large T antigen, and species-specific permissive factors. How these components interact to initiate and sustain viral DNA replication is not known. Toward that end, we have attempted to identify the viral target(s) of permissive factors. The functionally defined replication origins of polyomavirus and simian virus 40, two papovaviruses that replicate in different species (mice and monkeys, respectively), are composed of two functionally distinct domains: a core domain and an auxiliary domain. The origin cores of the two viruses are remarkably similar in primary structure and have common binding sites for large T antigen. By contrast, their auxiliary domains share few sequences and serve as binding sites for cellular proteins. It seemed plausible, therefore, that if cellular permissive factors interacted with the replication origin, their targets were likely to be in the auxiliary domain. To test this hypothesis we constructed hybrid origins for DNA replication that were composed of the auxiliary domain of one virus and the origin core of the other and assessed their capacity to replicate in a number of mouse and monkey cell lines, which express the large T antigen of one or the other virus. The results of this analysis showed that the auxiliary domains of the viral replication origins could substitute for one another in DNA replication, provided that the viral origin core and its cognate large T antigen were present in a permissive cellular milieu. Surprisingly, the large T antigens of the viruses could not substitute for one another, regardless of the species of origin of the host cell, even though the two large T antigens bind to the same sequence motif in vitro. These results suggest that species-specific permissive factors do not interact with the origin-auxiliary domains but, rather, with either the origin core or the large T antigen or with both components to effect DNA replication.     

A unique subpopulation of murine DNA polymerase alpha/primase specifically interacts with polyomavirus T antigen and stimulates DNA replication.

Murine cells or cell extracts support the replication of plasmids containing the replication origin (ori-DNA) of polyomavirus (Py) but not that of simian virus 40 (SV40), whereas human cells or cell extracts support the replication of SV40 ori-DNA but not that of Py ori-DNA. It was shown previously that fractions containing DNA polymerase alpha/primase from permissive cells allow viral ori-DNA replication to proceed in extracts of nonpermissive cells. To extend these observations, the binding of Py T antigen to both the permissive and nonpermissive DNA polymerase alpha/primase was examined. Py T antigen was retained by a murine DNA polymerase alpha/primase but not by a human DNA polymerase alpha/primase affinity column. Likewise, a Py T antigen affinity column retained DNA polymerase alpha/primase activity from murine cells but not from human cells. The murine fraction which bound to the Py T antigen column was able to stimulate Py ori-DNA replication in the nonpermissive extract. However, the DNA polymerase alpha/primase activity in this murine fraction constituted only a relatively small proportion (approximately 20 to 40%) of the total murine DNA polymerase alpha/primase that had been applied to the column. The DNA polymerase alpha/primase purified from the nonbound murine fraction, although far more replete in this activity, was incapable of supporting Py DNA replication. The two forms of murine DNA polymerase alpha/primase also differed in their interactions with Py T antigen. Our data thus demonstrate that there are two distinct populations of DNA polymerase alpha/primase in murine cells and that species-specific interactions between T antigen and DNA polymerases can be identified. They may also provide the basis for initiating a novel means of characterizing unique subpopulations of DNA polymerase alpha/primase.     

Excision of the plasmid containing the inserted human satellite DNA from Chinese hamster chromosomes after fusion of hamster and human cells

Fusion of the Chinese hamster stably transformed Tk+ cells containing chromosomally integrated plasmid with a fragment of human satellite III DNA (HS3), with mitomycin C-treated human cells (B-lymphoma, line Raji) results in amplification and excision of heterogeneous plasmid material from hamster chromosomes. Some of these plasmids contain HS3. Functional activity of HS3 in the initiation of DNA replication is shown in transient transfection experiments. The results indicate that mitomycin C induces in human cells some trans-acting factors (possibly proteins) activating a replication origin within HS3 DNA and leading to plasmid replication in situ and their excision from chromosomes.     

A region of the polyoma virus genome between the replication origin and late protein coding sequences is required in cis for both early gene expression and viral DNA replication.

Deletion mutants within the Py DNA region between the replication origin and the beginning of late protein coding sequences have been constructed and analysed for viability, early gene expression and viral DNA replication. Assay of replicative competence was facilitated by the use of Py transformed mouse cells (COP lines) which express functional large T-protein but contain no free viral DNA. Viable mutants defined three new nonessential regions of the genome. Certain deletions spanning the PvuII site at nt 5130 (67.4 mu) were unable to express early genes and had a cis-acting defect in DNA replication. Other mutants had intermediate phenotypes. Relevance of these results to eucaryotic "enhancer" elements is discussed.     

Amplification of polyomavirus DNA sequences stably integrated in rat cells.

To investigate the mechanism by which the polyomavirus large T antigen (T-Ag) promotes amplification of integrated viral sequences, we constructed a rat cell line, Hy2-ts5, carrying two different inserts of polyomavirus DNA. The first insert, designated the middle T (pmt) locus, was devised to analyze homologous recombination between two defective copies of pmt lying 3.3 kb apart on the same chromosome. Reconstitution of a functional pmt by spontaneous recombination occurred at a rate of about 2 x 10(-7) per cell generation. The second locus contained the polyomavirus large T (plt) gene carrying a temperature-sensitive mutation and producing a nonfunctional large T-Ag at 39 degrees C. A shift to the permissive temperature for as little as 24 h induced the production of a functional large T-Ag which, in turn, promoted homologous recombination in the pmt locus at a rate close to 1.0 per cell generation. The particularity of this system is that it allowed recombination products to be analyzed as early as a single cell doubling following the initial recombinational event. Amplification occurred by successive duplications of a discrete sequence in the viral insert. Unequal sister chromatid exchange was ruled out as the recombination mechanism promoted by large T-Ag. Instead, we proposed a model of nonconservative recombination involving mispairing between homologous sequences.