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

Recombination and its roles in DNA repair, cellular immortalization and cancer

Genetic recombination is the creation of new gene combinations in a cell or gamete, which differ from those of progenitor cells or parental gametes. In eukaryotes, recombination may occur at mitosis or meiosis. Mitotic recombination plays an indispensable role in DNA repair, which presumably directed its early evolution; the multiplicity of recombination genes and pathways may be best understood in this context, although they have acquired important additional functions in generating diversity, both somatically (increasing the immune repertoire) and in germ line (facilitating evolution). Chromosomal homologous recombination and HsRad51 recombinase expression are increased in both immortal and preimmortal transformed cells, and may favor the occurrence of multiple oncogenic mutations. Tumorigenesis in vivo is frequently associated with karyotypic instability, locus-specific gene rearrangements, and loss of heterozygosity at tumor suppressor loci - all of which can be recombinationally mediated. Genetic defects which increase the rate of somatic mutation (several of which feature elevated recombination) are associated with early incidence and high risk for a variety of cancers. Moreover, carcinogenic agents appear to quite consistently stimulate homologous recombination. If cells with high recombination arise, either spontaneously or in response to "recombinogens," and predispose to the development of cancer, what selective advantage could favor these cells prior to the occurrence of growth-promoting mutations? We propose that the augmentation of telomere-telomere recombination may provide just such an advantage, to hyper-recombinant cells within a population of telomerase-negative cells nearing their replicative (Hayflick) limit, by extending telomeres in some progeny cells and thus allowing their continued proliferation.

Clone-specific high-frequency retrotransposition of a recombinant virus containing a VL30 promoter in SV40-transformed NIH3T3 cells

A recombinant virus, containing the promoter of a VL30 LTR and tagged with the neomycin gene as a selection and indicator marker, was constructed to investigate transposition events in NIH3T3 cells after SV40 transformation. This retroviral construct was transfected into psi/CRE packaging cells, and pseudovirions were used to infect NIH3T3 cells. Clones resistant to G418 bearing single-copy integrations of the recombinant virus were isolated and transformed by SV40 virus. Transpositions were detected through RFLPs with a neomycin probe and 'retrotransposition' was further confirmed by inverse PCR and DNA sequencing of transposed and parental copies. We found that: (1) retrotransposition of this recombinant virus occurred with a high frequency in a parental clone transformed with SV40 virus suggesting that the frequency of retrotransposition depended on the initial site of provirus integration; (2) the transposition frequency was independent of the transcription level of the recombinant construct; and (3) analysis of transposition-positive transformants showed that the high transposition frequency appeared to be associated with the induction of endogenous reverse transcriptases.

Site-specific in situ amplification of the integrated polyomavirus genome: a case for a context-specific over-replication model of gene amplification

The fate of the genome of the polyoma (Py) tumor virus following integration in the chromosomes of transformed rat FR3T3 cells was re-examined. The viral sequences were integrated at a single transformant-specific chromosomal site in each of 22 transformants tested. In situ amplification of the viral sequences was observed in 24 of 34 transformants analyzed. Large T antigen, the unique viral function involved in initiating DNA replication from the viral origin, was essential for the amplification process. There was an absolute requirement for a reiteration of viral sequences and the extent of the reiteration affected the degree of amplification. The reiteration may be important for homologous recombination-mediated resolution of in situ amplified sequences. Among 11 transformants harboring a 1 to 2 kb repeat, the degree of amplification was transformant-specific and varied over a wide range. At the high end of the spectrum, the genome copy number increased 1300-fold at steady state, while at the low end, amplification was below twofold. Some aspect of the host chromatin at the site integration that affected viral gene expression, also directly or indirectly modulated the amplification. Use of high-resolution electrophoresis for the analysis of the integrated amplified sequences revealed a recurring novel pattern, consisting of a ladder with numerous bands separated by a constant distance approximately the size of the Py genome. We suggest that this pattern was generated by conversion of the amplified viral genomes to head to tail linear arrays with cell to cell variations in the number of genome repeats at single, transformant-specific, chromosomal sites. In light of the known "out of schedule" firing of the Py origin, we propose an "onion skin" structure intermediate and present a homologous recombination model for the conversion from onion skins to linear arrays. The relevance of the in situ amplification of the Py genome to cellular gene amplification is discussed. Finally, these results clarify our understanding of the integration of the Py genome in rat cells. They suggest that, in most cases, the multiple bands previously described in Py-transformants are likely to reflect genome amplification rather than multiple independent integration events, as assumed in the past. This interpretation is congruent with the accepted view that the integration of the Py genome is a rare and rate-limiting event in transformation.

Induction of duplication reversion in human fibroblasts, by wild-type and mutated SV40 T antigen, covaries with the ability to induce host DNA synthesis

Intrachromosomal homologous recombination, manifest as reversion of a 14-kbp duplication in the hypoxanthine phosphoribosyl transferase (HPRT) gene, is elevated in human cells either stably transformed or transiently transfected by the SV40 (simian virus 40) large T antigen gene. Following introduction of wild-type SV40, or any of several T-antigen point mutations in a constant SV40 background, we observed a strong correlation between the stimulation of chromosomal recombination and induction of host-cell DNA synthesis. Moreover, inhibitors of DNA replication (aphidicolin and hydroxyurea) suppress SV40-induced homologous recombination to the extent that they suppress DNA synthesis. Stable integration of plasmids encoding T antigen also augments homologous recombination, which is suppressed by aphidicolin. We infer that the mechanism by which T antigen stimulates homologous recombination in human fibroblasts involves DNA replicative synthesis.

Expression of SV40 large T antigen stimulates reversion of a chromosomal gene duplication in human cells

Transformation of human cells is characterized by altered cell morphology, frequent karyotypic abnormalities, reduced dependence on growth factors and substrate, and rare "immortalization"-clonal acquisition of unlimited proliferative potential. We previously reported a marked increase in DNA rearrangements, arising between two duplicated segments in a transfected plasmid substrate, for five immortal human cell lines relative to three normal fibroblast strains [Finn et al. (1989) Mol. Cell. Biol. 9, 4009-4017]. We have now assessed reversion of a 14-kilobase-pair duplication within the hypoxanthine phosphoribosyl transferase (HPRT) gene locus, in a fibroblast strain during its normal replicative lifespan and after stable transformation with SV40 large-T antigen. Revertants, selected under HPRT-dependent growth conditions immediately after purging preexisting HPRT+ cells, were confirmed as HPRT+ by hypoxanthine incorporation and 6-thioguanine sensitivity. Southern blot analyses indicate loss from most revertant clones of a restriction fragment representing the duplicated HPRT region, as predicted for homologous recombination between the 14-kilobase-pair repeats. Amplification of a subregion of HPRT mRNA implicated deletion of duplicated exons in 93% of revertant colonies. Reversion to HPRT+ was unaltered during the normal in vitro lifespan of these cells, but increased in 9 clones stably transformed with large-T antigen (mean = 3.8-fold; each P < 10(-5)). Stimulation of HPRT-reversion is abrogated in a variety of T-antigen mutants, and depends on continued induction of T antigen by glucocorticoid in two clones tested 10-30 doublings before replicative senescence. Since no immortal subclones arose from these clones, elevated reversion must precede immortalization. Increased DNA rearrangements, in cells expressing T-antigen, could facilitate the rare concurrence of multiple mutations necessary for immortalization.

Tumor suppressor p53 mutations and breast cancer: a critical analysis

Alterations in the tumor suppressor gene p53 are the most commonly identified changes in cancer, including neoplasia of the breast. The activity of p53 is regulated post-translationally. Phosphorylation state, subcellular localization, and interaction with any of a number of cellular proteins are likely to influence the function of p53. The exact effect of p53-mediated growth suppression seems to be cell-type specific but appears to be directly related to the ability of p53 to act as a specific transcriptional activator. The role that transcriptional repression plays in the function of WT p53 is less clear. It is also possible that p53 has a more direct activity in DNA replication and repair. Most documented p53 mutations result in single amino acid substitutions which may confer one or more of a spectrum of transforming abilities on the protein. Mutation may lead to nuclear accumulation of p53 protein; however, inactivation of p53 by nuclear exclusion and interaction with the mdm2 protein also appear to be important in tumorigenesis. Used in conjunction with other established factors, accumulation of cellular p53 may be a useful prognostic indicator in breast cancer. A syngeneic mouse model system yielded evidence that p53 mutations are important in the early, preneoplastic stages of mammary tumorigenesis. This murine system may provide the ability to investigate the functions of p53 in the early stages of breast cancer which are technically difficult to examine in the human system.

Persistence of the SV40 early region without expression in permissive simian cells

SV40 containing recombinant vectors were introduced into permissive simian, non-permissive rodent and semi-permissive human cell lines, and assayed for transformation. All mouse and human cell clones expressed T-antigen (T-Ag) and were morphologically transformed when they contained only the wt T-Ag gene (E-SV40) or the entire wt viral genome with an interrupted late region. However, of 63 simian clones with these recombinant vectors, none became morphologically transformed and T-Ag containing cells were rare or absent. Nearly all simian cell lines made either no detectable early SV40 RNA or only small amounts of viral RNA but contained viral DNA restriction fragments similar to those in the original recombinant vectors. Functional T-Ag genes were recoverable from several cell clones and used to regenerate infectious virus. Hence, T-Ag gene expression had been suppressed. We found two conditions where T-Ag expression was activated. In a BSC-1 cell line containing E-SV40 DNA, subsequent introduction of a vector with a functional viral late coding region (L-SV40) resulted in the appearance of T-Ag and transformation. These findings suggest that L-SV40 sequences activate or enhance T-Ag expression and that this activation requires a functional Vpl gene. We found also, that vectors with E-SV40 DNA from the bipartite variant EL-SV40 consistently transformed simian CV-1 cells. Transformation was shown to be effected by the multiple alterations present in the regulatory region of this variant.

Analysis of proviral integration in human mammary epithelial cell lines immortalized by retroviral infection with a temperature-sensitive SV40 T-antigen construct

A panel of eight conditionally immortal lines derived by infection of human breast epithelial cells with an amphotropic retrovirus transducing a ts mutant of SV40 large T-antigen was analyzed with respect to individual retroviral integration patterns. Each line contained multiple integration sites which were clonal and stable over extended passage. Similar integration patterns were observed between individual lines arising separately from the same stock of pre-immortal cells, suggesting a common progenitor. Retroviral integration analysis of pre-immortal cells at different stages of pre-crisis growth showed changes indicative of a progressive transition from polyclonality to clonality as the cells approached crisis. Each of the immortal lines contained a sub-set of the integration sites of their pre-immortal progenitors, with individual combinations and copy numbers of sites. Since all the cell lines appeared to originate from single foci in separate flasks, it is likely that each set arose from a common clone of pre-immortal cells as the result of separate genetic events. There was no evidence from this analysis to suggest that specific integration sites played any part either in the selection of pre-crisis clones or in the subsequent establishment of immortal lines.

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.

Modulation of accessory cell function of immortalized bone marrow-derived macrophages by granulocyte/macrophage colony-stimulating factor

To generate cloned macrophage populations with sensitivity towards granulocyte/macrophage colony-stimulating factor (GM-CSF), bone marrow-derived macrophages (BMM phi) were immortalized by transformation with SV40. A panel of transformed clones was established. The majority of clones represented independently derived transformants, as evidenced by restriction fragment length polymorphism using genomic DNA digested with EcoRI and TaqI and the 5.2 kb SV40 DNA for hybridization analysis. The cells belong to the macrophage lineage according to several criteria, e.g. the presence of nonspecific esterase, their phagocytic capacity and their morphology. Many clones were potent antigen-presenting cells (APC), without exogenous stimulation. Two clones, which did not act efficiently as APC when used untreated, were positively responsive to GM-CSF. GM-CSF stimulation of both clones resulted in potent APC capacity. I-A alpha, I-A beta and gamma chain-specific transcripts were observed upon stimulation with GM-CSF, corresponding to detectable levels of class II surface display as revealed by cytofluorometric analysis. Thus the macrophage clones established will allow dissection of the differential effects of GM-CSF on the parameters of antigen presentation.

The interaction of SV40 large T antigen with unspecific double-stranded DNA: an electron microscopic study

T antigen, an early protein encoded by simian virus 40 (SV40), is a specific DNA-binding protein with high affinity for elements in the viral origin of replication where it forms a double-hexameric complex as a prerequisite for DNA untwisting and, in the presence of ATP hydrolysis, for DNA unwinding. Like other specific DNA-binding proteins, T antigen also associates with DNA strands of random sequence albeit at reduced affinity. In addition, T antigen is able to unwind unspecific DNA sequences starting from internal binding sites. This property could be a step in the pathway leading to the chromosomal rearrangements that are frequently observed in SV40-transformed cells. This possibility prompted us to investigate the binding of T antigen to unspecific DNA using electron microscopy. We observed that the protein binds randomly to many unspecific DNA sites excluding a preference for particular DNA sequences or structural features. Addition of ATP to the binding buffer induces the formation of oligomeric, possibly hexameric, T antigen complexes that frequently align to form long arrays of DNA-bound protein. Magnesium salts induce the formation of tightly packed T antigen aggregates which bind to DNA to form many DNA branches and loops that emanate from the aggregated protein core. Upon ATP hydrolysis, aggregated T antigen catalyzes the unwinding of DNA duplices.

A stable flank of unstable lymphotropic papovavirus integration sites is associated with a cellular S1 nuclease-sensitive sequence

Integration of viral DNA sequences is associated with stable transformation by viruses of the polyomavirus genus. In LPV-HE cells, a hamster embryonal cell line transformed by the African green monkey lymphotropic papovavirus (LPV), viral integration is unstable during tissue culture passage, leading to subclones with rearrangements of the original integration locus. Three of four viral integrations that were molecularly cloned together with flanking cellular sequences are identical in one junction but are different from each other at the other flank. The "stable" flank which is already present in early passage cells contains an S1 nuclease-sensitive sequence located approximately 60 bp outside of the viral-cellular junction. The presence of this site may contribute to the stability of the flanking region.

The role of recombinational hotspots in genome instability in mammalian cells

Genome instability has been associated with progression of transformed cells to high tumorigenicity. Although genome instability may result from a variety of factors, some studies suggest that DNA in the region of a chromosome rearrangement can subsequently have much higher rates of DNA deletions or gene amplification. One approach to studying the factors that produce these high rates of DNA rearrangement is by analysis of unstable integration sites for DNA transfected into mammalian cells. Integrated sequences commonly show a temporary instability, and at rare locations this instability is continuous and can be observed even after multiple subclonings. These continuously unstable locations undergo DNA amplification of both the integrated sequences and the surrounding cell DNA, and it can occur either at the original site or on episomes after looping out from the chromosome. Because the adjacent cell DNA plays a role in this instability, and the region can be shown to be stable before integration, the results indicate that these recombinational hotspots can be formed de novo by the process of integration. Current studies are attempting to determine which sequences are responsible for the high rates of recombination and whether similar types of event are involved in the instability associated with endogenous cellular genes in cancer cells.