Inhibition of simian virus 40 T-antigen expression by cellular differentiation.

Murine 3T3T stem cells transfected with pSV3neo DNA were employed to study the effects of somatic cell differentiation on simian virus 40 (SV40) T-antigen expression. This experimental approach was used because the 3T3T cell line is a well-characterized in vitro adipocyte differentiation system and the pSV3neo plasmid contains the early region of the SV40 genome and a selective marker, G418 resistance. Cell clones containing stably integrated pSV3neo which expressed T antigen were isolated in G418-containing medium. Most of these cell clones differentiated poorly. However, several clones retained the ability to efficiently differentiate into adipocytes, and with these cell clones, it was established that adipocyte differentiation markedly repressed T-antigen expression. The differentiation-specific repression of T-antigen expression did not result from a loss of proliferative potential associated with terminal differentiation, because it was observed in adipocytes that could be restimulated to proliferate. In such cells, restimulation of cell growth induced reactivation of T-antigen expression. Repression of T-antigen expression was also demonstrated during differentiation of SV40 T-antigen-immortalized human keratinocytes. These results establish that the process of cellular differentiation can repress T-antigen expression in at least two distinct biological systems.     

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.     

Transformation of human cultured fibroblasts with plasmids carrying dominant selection markers and immortalizing potential

The disadvantages of using human cultured cells for biochemical and genetic studies are their limited lifespan in vitro and their lack of chemical selection markers. These problems are now overcome by transfecting human cultured fibroblasts with the pSV3-gpt and pSV3-neo plasmid DNA which carry genes coding for the immortalizing SV40 large T-antigen and dominant selection markers. Transformed human fibroblasts were obtained at a frequency of about 10(-5) with both selection systems. These transformed cells showed a twofold increase in growth rate and three to tenfold increase in cell number at confluence. The improved growth characteristics were associated with the expression of the SV40 T-antigen detected with immunoprecipitation. These cell lines also changed from their usual spindle shapes to an epithelioid morphology characteristic of transformed cells. From 60 to 100% of the cells transfected with pSV3 plasmid DNA demonstrated numerical and structural abnormalities in their karyotypes. Cells transfected with DNA from a similar plasmid, pSV2-neo, which differed from the pSV3-neo plasmid only by missing the sequence encoding the complete early region of SV40, neither expressed T-antigen nor showed any change in morphology, improvement in growth characteristics or abnormalities in karyotype. However, they were still selectable with the aminoglycoside G-418. Therefore, by appropriate choice of vector plasmids, dominant selection markers and improved growth characteristics can be imparted separately or simultaneously to human fibroblasts. The morphological, biochemical and chromosomal changes resulting from such transformations must be recognized in using this approach for biochemical and genetic studies.     

Transformation of DNA repair-deficient human diploid fibroblasts with a simian virus 40 plasmid

Fibroblasts from patients with xeroderma pigmentosum (XP) complementation groups A, C, D, E, and G, as well as Bloom syndrome (BS) and Fanconi anemia (FA) have been transfected with a plasmid, pSV7, containing the early region of Simian virus 40 (SV40). All of the cultures exhibited cytologic changes characteristic of transformed cells and expressed T-antigen. They also contained integrated copies of DNA derived from the vector, and in several cases, extrachromosomally replicated DNA. Not all of the transfected cultures became immortalized. The transformed xeroderma pigmentosum (XP) cultures retained their UV-sensitive phenotype in all but one case. The BS and FA cell lines retained their characteristic phenotype. All of the cultures, except the BS cells, can be readily transfected with the plasmids, pSV2neo and pSV2gpt.     

Construction of cell lines that regulate by temperature the amplification and expression of influenza virus non-structural protein genes.

Monkey cell lines have been transformed with a mixture of plasmids pSV2neo and pSLVa232N, a derivative of plasmid pSLVa232 (Portela et al., 1985b). Plasmid pSLVa232N contained the influenza virus genes encoding non-structural proteins under the control of the SV40 late promoter in pSLts1 vector that includes the SV40 ori and the tsA209 T-antigen gene. At restrictive temperature, plasmid sequences remained stably integrated in the cell genome, but upon temperature shift-down, defined circular DNA molecules were generated and amplified up to 2000-5000 copies/cell. Restriction analysis, Southern blot hybridization and partial sequencing indicate that one such episome, pC5, was derived from the integrated plasmid sequences by a homologous recombination event that led to deletion of the pBR322 sequences included in pSLVa232N. Concomitant with gene amplification, an induction of 20-65-fold in the expression of NS1 and NS2 proteins was observed after temperature shift-down. Thus, gene cloning into vector pSLts1 and transformation at restrictive temperature of cells permissive for SV40 DNA replication, appears to be a useful strategy for the controlled amplification and expression of cloned genes.     

Transformation of bone marrow cells in rodents by recombinant plasmid pBRSV

Bone marrow cells (mouse strain CBA/Ca and Syrian hamster cells) were transformed with pBRSV DNA containing T-antigen of the SV40 virus. The SV40 T-antigen in transformed cell was detected in 0.5% cases by immunofluorescence with specific antibodies. Extrachromosomal localization of recombinant DNA was shown by means of retransformation of E. coli cells with cytoplasmic spleen DNA from mice previously injected intravenously the transformed bone marrow cells.     

Analysis of Minimal Functions of Simian Virus 40 II. Enhancement of Oncogenic Transformation in Vitro by UV Irradiation

After light UV irradiation (5,000 to 10,000 ergs/mm²) “complete” and “defective” simian virus 40 (SV40) showed an enhancement of oncogenic transformation capacity in Syrian hamster kidney cells in vitro up to 180 and 270% of the controls, respectively. Simultaneously with the enhancement of transformation, an increase in T-antigen induction was observed in CV-1 cells infected with light UV-irradiated SV40; infectivity, however, was correspondingly reduced by 1 log₁₀. After strong UV irradiation (10,000 to 80,000 ergs/mm²) of “complete” and “defective” SV40, transformation capacity in vitro proved to be the most resistant viral function. It was only slightly reduced in comparison with a 4 to 5 log₁₀ reduction of infectivity. T-antigen induction of SV40 was also equally resistant to strong UV irradiation. We found no evidence of “multiplicity reactivation” involved in the high resistance of transformation capacity of SV40 after UV irradiation. Syrian hamster kidney cells transformed in vitro by UV-irradiated SV40 contained the SV40-specific T-antigen and showed the same morphology and growth characteristics as cells transformed by non-irradiated “complete” or “defective” SV40. They induced malignant tumors after subcutaneous inoculation into Syrian hamsters.     

The second large simian virus 40 T-antigen exon contains the information for maximal cell transformation

Microinjection of early simian virus 40 (SV40) DNA fragments has shown that maximal transformation of rat cells (Ref 52) is a property of the second SV40 T-antigen exon. Expression of this particular T-antigen region was obtained by coinjection of the $\text{Taq}\text{Bam}$ DNA fragment with the early promoter/enhancer $\text{Hpa}\text{II}\text{Bgl}\text{I}$ fragment. Microinjection of the DNA fragment mixture induced two categories of transformants; namely, maximally and minimally transformed cells. The maximally transformed cells synthesize two $\text{Taq}\text{Bam}$-specific polypeptides, and the minimally transformed cells only the lower molecular weight form. Both types of transformants contain the cellular p52 protein at high concentrations. Furthermore, maximal transformation of Ref 52 cells requires the carboxy terminus of the T-antigen. Cells transformed by microinjection of the SV40 Pst A-fragment display different parameters of maximally transformed cells but not anchorage-independent growth.     

Three distinct effects of SV40 T-antigen gene transfection on cellular differentiation

SV40 large T-antigen-induced transformation has been reported to block differentiation, but the mechanism(s) of this effect has not been established. The results presented here show that stable transfection of the SV40 T-antigen gene, via the pSV3neo plasmid, has at least three distinct effects on 3T3T adipocyte differentiation. Cells first show a decreased ability to undergo predifferentiation growth arrest, which is a prerequisite for in vitro 3T3T adipocyte differentiation. However, if predifferentiation growth arrest is accomplished by use of stringent differentiation-inducing culture conditions, adipocyte differentiation can occur with high frequency. The pSV3neo-transfected cell clones also show other modifications of the adipocyte differentiation process, including changes in nonterminal (reversible) and terminal (irreversible) steps of adipocyte differentiation. When compared to nontransfected 3T3T cells, the cell clones containing pSV3neo require markedly reduced growth factor concentrations to restimulate proliferation of nonterminally differentiated adipocytes and the terminal step of differentiation is also blocked. These results suggest that integration of the T-antigen gene, through pSV3neo transfection, has multiple effects on the cellular mechanisms of differentiation. It does not block the differentiation process per se; rather it appears to make cells highly sensitive to proliferation signals, thereby making differentiation more difficult.     

Viral and cellular oncogene expression during progressive malignant transformation of SV40 transformed human fibroblasts.

In vitro investigation of the multistep neoplastic progression which occurs during transformation of human cells has been hindered by resistance of human cells to both immortalization and tumorigenicity (Mut. Res. 199; 273, 1988). Previously our laboratory established a cell line, HSF4-T12, by transfection of normal human foreskin fibroblasts with the plasmid pSV3-neo which contains the early genes of simian virus 40 (SV40). A multistep progression in karyotypic alterations and transformed phenotype occurred resulting in a neoplastic cell line that was immortal, transformed, and tumorigenic. We have examined changes in the SV40 proteins, large T (T-antigen) and small t (t-antigen) antigens, and in the cellular protein, p53, during progressive transformation of these cells. Total viral protein expression relative to total cellular protein increased following immortalization of HSF4-T12 as did the ratio of T-antigen to t-antigen. Interestingly, no significant change in DNA content accompanied immortalization. However, during the progressive in vitro transformation of HSF4-T12 which occurred primarily post-immortalization, DNA index increased to 1.6 but only small additional increases in T-antigen expression were seen. No consistent or critical role for t-antigen in development of the tumorigenic phenotype was found in this system.     

Extension of lifespan of human T lymphocytes by transfection with SV40 large T antigen.

Lymphocytes have a finite and predictable proliferative life span in culture similar to that observed in fibroblasts. In general, the senescence of human fibroblasts is inevitable and irreversible, but their proliferative life span can be extended by certain DNA tumor virus oncogenes, such as the large T antigen of the SV40 virus. Here, we show that human T lymphocytes (HTL) can be stably transfected with SV40 large T and that expression of T antigen extended the life span of T cell cultures. PHA-stimulated HTL were transfected with pSV3neo, an expression vector containing the SV40 early region and the neomycin resistance gene. Transfectants were selected for neomycin (G418) resistance. Control HTL, either mock transfected or transfected with pSV2neo (containing the neomycin resistance gene only), ceased proliferation after about 17 population doublings. In contrast, HTL transfected with pSV3neo underwent more than 170 doublings. pSV3neo-transfected cells expressed SV40 large T RNA, detectable by in situ hybridization, and SV40 T antigen, detectable by immunofluorescence. Greater than 95% of the transfected cells were CD4 positive. These results clearly show that SV40 large T enables HTL to escape senescence. Transfection with SV40 large T may be a valuable method for obtaining long term human T cell lines for studies of both aging and immunology.     

Establishment and characterization of a permanent pSV ori--transformed ataxia-telangiectasia cell line

A permanent ataxia-telangiectasia (A-T) cell line has been established from the fibroblast strain AT2SF after transfection with the bacterial plasmid pSV ori-, which contains replication origin-defective SV40 sequences. The original transfection frequency, as measured by transformed foci, was markedly reduced in two A-T strains when compared with either normal or xeroderma pigmentosum fibroblasts. As with SV40 virion-transformed fibroblasts, pSV ori--transformed cells entered a crisis phase, from which about one-fourth of the original clones from A-T and normal fibroblasts recovered. Both the pSV ori--transformed TAT2SF cell line and an SV40 virion-transformed AT5BI (GM5489) cell line retained their characteristic sensitivity to the lethal effects of ionizing radiation, as well as their X ray-resistant DNA synthesis. Southern blot analysis of cellular SV40 sequences demonstrated a single major integration site of pSV ori- in the AT2SF cells. In contrast, AT5BI cells transformed with SV40 virions demonstrated a high degree of heterogeneity of integrated viral sequences. Neither the TAT2SF nor the GM5489 transformed cell line contains any detectable freely replicating SV40 viral sequences, which are seen in many other semipermissive SV40-transformed cells.     

New acceptor cell for transfected genomic DNA: oncogene transfer into a mouse mammary epithelial cell line.

A line of mouse mammary epithelial cells (NMuMG) has been characterized for its ability to be stably transfected with exogenous DNA. A transfection frequency of at least 1 cell per 1,000 was obtained with the pSV2neo plasmid. Several thousand G418-resistant NMuMG cell clones can easily be generated in cotransfection of genomic DNA and pSV2neo. The NMuMG cells were isolated from normal mammary glands and do not form malignant lesions when injected into nude mice. We have cotransfected NMuMG cells with pSV2neo and genomic DNA from the human EJ bladder carcinoma line, a cell line which contains an activated c-rasH oncogene. When a pool of 4,700 G418-resistant colonies was injected into nude mice, tumors were obtained. These tumors contain a transfected human rasH gene. Genomic DNA transfection into a line of mouse epithelial cells, in combination with the selection of stable transfectants and tumor induction in nude mice, can be used to screen human tumor DNA for the presence of activated oncogenes.     

Stable transformation of mouse teratocarcinoma stem cells with the dominant selective marker Eco.gpt and retention of their developmental potentialities

Transformation of PCC4 mouse teratocarcinoma stem cells was obtained using a dominant selective marker, the enzyme xanthine-guanine phosphoribosyltransferase (XGPRT), coded by the bacterial Eco.gpt gene placed under the control of the early SV40 genes in the vector pSV2gpt. An average of 20 colonies of transformed cells was obtained, using the calcium phosphate technique, 10 microg DNA vector, no carrier DNA and 1 x 10(6) recipient cells. Five independent Eco.gpt-transformed PCC4 cell lines were propagated in selective medium and assayed for XGPRT activity. All of them had the ability to convert [14C]xanthine to xanthine monophosphate. pSV2gpt sequences were present and associated with high mol. wt. cellular DNA. pSV2gpt sequences and XGPRT activity were both conserved in the three clones that were propagated in non-selective medium for 30 generations. The transformed PCC4 cells retained their ability to produce, in host mice, teratocarcinoma tumors composed of embryonal carcinoma and various differentiated tissues. Thus, pSV2gpt can be used as a dominant marker to select teratocarcinoma stem cells co-transformed with genes that are not selectable by themselves.     

Biological and biochemical characterization of an SV40-transformed xeroderma pigmentosum cell line

We have isolated a subclone of the SV40-transformed xeroderma pigmentosum (XP) cell line SV40XP12RO. The cell line, designated M1, is highly sensitive to ultraviolet light and is deficient in unscheduled DNA synthesis. The isoenzyme, HLA profile and karyotype of the cell line is presented. The structure and function of the resident SV40 genome is analysed. The M1 clone contains a complete copy of the SV40 genome flanked by partial SV40-DNA copies in a head-to-tail arrangement. The large T-antigen is defective in the ability to induce SV40-DNA replication. The M1 subclone is an efficient recipient of DNA in transfection experiments. Transfection of these cells with the pSV₂gpt plasmid shows that the M1 subclone is as efficient as the NIH 3T3 cell line in uptake and expression of foreign DNA. This cell line should be suitable for genetic analysis of the xeroderma pigmentosum defect. It should also be useful for the study of gene expression in human cells.     

Cellular mutation mediates T-antigen-positive revertant cells resistant to simian virus 40 transformation but not to retransformation by polyomavirus and adenovirus type 2.

T-antigen-positive transformation revertant cell lines were isolated from fully simian virus 40 (SV40)-transformed Fisher rat embryo fibroblast cells (REF 52 cells) by methionine starvation. Reversion of the transformed cells (SV-52 cells) was caused by a mutation within the cellular genome. To demonstrate this, we isolated SV40 DNA from the host genome, inserted it into plasmid pSPT18 DNA, cloned it in Escherichia coli, and microinjected it into the nuclei of the REF 52 cells. Fully transformed cells were obtained with the same efficiency (20 to 25%) as after microinjection of wild-type SV40 DNA I. Furthermore, the revertant cells were resistant to retransformation by SV40. Following microinjection of wild-type SV40 DNA I, 42 independent cell lines were isolated. Cells of all analyzed lines acquired additional SV40 DNA copies, but changes in the cell morphology or growth characteristic were not demonstrable. However, the revertants were retransformable with a high efficiency after polyomavirus and adenovirus type 2 infections or microinjection. Also, fusion of the revertant cells with the grandparental REF 52 cells led to restoration of the transformed state.     

Successful production of transgenic rats

Abstract

DNA of pSV2‐gpt‐gE1A or SV2‐cat microinjected into pronuclei of fertilized rat eggs was found incorporated into chromosomes of 3 out of 48 (6.3%) or 10 out of 66 (15.2%) new born rats, respectively. The transgenic rats carrying SV2‐cat DNA transmitted the transgenes to their G₁ progeny.