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.     

An SV40-transformed xeroderma pigmentosum group D cell line: establishment, ultraviolet sensitivity, transfection efficiency and plasmid mutation induction

Fibroblasts from a patient with xeroderma pigmentosum complementation group D were treated with Simian virus 40 to establish a transformed cell line suitable for studies of DNA-mediated gene transfer. After progressing through 2 crises, a stable line, XP6Be(SV40), was established and cultured for more than 1 year. This line retains the characteristic xeroderma pigmentosum ultraviolet hypersensitivity and is able to complement a SV40-transformed group A line when fused and assayed for ultraviolet radiation inhibition of colony-forming ability. XP6Be(SV40) expressed high levels of transfected chloramphenicol acetyltransferase activity (0.1 nmole X mg-1 X min-1) in a transient expression assay, showed stable expression of transfected gpt or neo genes (frequency 1-20 X 10(-5)), and permitted replication of the mutagenesis shuttle vector plasmid, pZ189. Ultraviolet treatment (500 J X m-2) of pZ189 prior to replication in XP6Be(SV40) resulted in a large reduction in plasmid yield (5% survival) and a 60-fold increase in the mutation frequency, reflecting the reduced ability of these cells to repair ultraviolet-damaged transfecting DNA. This cell line provides the opportunity to utilize transfection studies in cells with the xeroderma pigmentosum group D defect in excision repair.     

The expression of the Escherichia coli uvrA gene in human cells

Cells cultured from xeroderma pigmentosum (XP) patients are defective in excision repair of damaged DNA specifically at the incision step. In Escherichia coli this step is mediated by the UvrA, UvrB and UvrC gene products. Our goal is to express each of these genes in XP cells, singly or in combination, and to determine the most suitable conditions for generating faithful E. coli Uvr protein copies in functional concentrations and properly localized for the eventual repair of damaged chromosomal DNA or DNA which is introduced exogenously. The E. coli gpt gene in pSV2gpt is used as a selection marker for uvr gene transfection into XP cells. The uvr genes were cloned into composite pBR322, SV40 and gpt vectors in which each E. coli gene is flanked by individual SV40 regulatory elements. SV40-transformed XP-A cells were transfected with pSV2uvrASV2gpt, gpt+ colonies were selected, and cell lines established. Several lines were examined in detail. Cell lines 714 and 1511 contain uvrA together with flanking SV40 regulatory elements integrated intact in genomic DNA and express UvrA protein as well as a 95,000-dalton UvrA-related protein. The expression of uvrA was found to be 50-100-fold lower than the expression of gpt. Attempts were made to assay the mammalian UvrA protein for functionality, but endogenous activities interfered with assays for each of the UvrA protein's three activities. The peptide maps derived from partial proteolysis of the "mammalian" UvrA protein are identical to the E. coli UvrA protein. The sub-cellular location of UvrA protein in uvrA+ XP cells was investigated by fractionation of cell extracts in which an indirect immunofluorescence method revealed its location as being largely extra-nuclear. Two uvrA+ cell lines were examined for their UV-resistant phenotype and not unexpectedly were found not to be reverted to a state of repair proficiency.     

Transformation and immortalization of diploid xeroderma pigmentosum fibroblasts

Diploid xeroderma pigmentosum (XP) skin fibroblast strains from various XP-complementation groups (B, C, G, and H) were transformed with an origin-defective SV40 early region or with the pSV3 gpt plasmid. In the latter case, transfected cells were selected for their ability to express the dominant xgpt gene. Immortalized cell lines were obtained, from XP-complementation groups C (8CA, 3MA, and 20MA; XP3MA and XP20MA were formerly considered to belong to complementation group I), G (2BI and 3BR), and H (2CS). No immortalized cells could be isolated from complementation group B (11BE). The immortalization frequency of wild-type diploid fibroblasts and diploid cultures from XP patients was not significantly increased by cotransfection with the SV40 early region plus several selected viral and cellular oncogenes. In fact, co-transfection with some of the oncogenes caused a marked decrease of the transformation frequency. The observed immortalization occurred at a frequency of approximately 5 x 10(-8).     

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.     

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.     

Replicon sizes in non-transformed and SV40-transformed cells, as estimated by a bromodeoxyuridine photolysis method

Replicon sizes were measured in Simian Virus 40 (SV40)-transformed and untransformed normal human, xeroderma pigmentosum (XP), and mouse 3T3 cells with an X-ray plus bromodeoxyuridine (BUdR) photolysis method. Replicon sizes in SV40-transformed cells were at least twice those in untransformed counterparts, but DNA fork displacement rates were only slightly increased.     

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.     

Analyses of mutation in pSV2gpt-transformed CHO cells

We have developed a system to study mutations which affect expression of the E. coli xanthine-guanine phosphoribosyl transferase (XPRT) gene (gpt) in hypoxanthine-guanine phosphoribosyl transferase-deficient (HPRT-) Chinese hamster ovary (CHO) cells that have been transformed by the plasmid pSV2gpt. Several gpt-transformed cell lines have been isolated and characterized with respect to integrated pSV2gpt sequences, expression of the gpt gene, and cytotoxic and mutagenic responses to UV light. While the gpt-transformed CHO and wild-type CHO-K1-BH4 cell lines have similar cytotoxic responses to UV light, the gpt-transformed cell lines respond differently from the parental CHO-K1-BH4 cell line in terms of mutation induction. As with CHO-K1-BH4 HPRT mutants, spontaneous or induced XPRT mutants derived from the gpt+ cell lines can be selected for 6-thioguanine resistance (TGr). Analysis of cell-free extracts from a number of these TGr clones indicates that the mutant phenotype is due to the absence of XPRT activity. One transformant, designated AS52, has previously been described in limited detail. Here we describe additional characteristics of this cell line, as well as several related transformants.     

Studies on p53 and Bax protein expression in Cockayne syndrome cells after UV irradiation and interferon-beta treatment

Human interferon (HuIFN) has a protective effect against ultraviolet (UV)-induced killing of Cockayne syndrome (CS) and xeroderma pigmentosum (XP) cells. Irradiation with ultraviolet (UV) resulted in nuclear accumulation of p53 in normal human fibroblast cells, and this accumulation was suppressed by treatment with HuIFN-beta. On the other hand, a large amount of p53 was found in both nuclear and cytoplasmic fractions of one SV40-transformed XP and two SV40-transformed CS cell strains irrespective of UV irradiation. Treatment with HuIFN-beta reduced the level of pro-apoptotic Bax protein without suppression of nuclear accumulation of p53 in the CS cells but not in the XP cells. These findings suggest that there are different mechanisms of UV-refractoriness caused by HuIFN-beta in UV-sensitive CS and XP cells.     

Efficient immortalization and morphological transformation of human fibroblasts by transfection with SV40 DNA linked to a dominant marker

Immortal cell lines are essential for genetic and biochemical studies. Unlike rodent cells, which will form continuously growing cultures either spontaneously or after infection with an oncogenic virus (e.g., Simian Virus 40 (SV40)), human cells fail to form continuous cell lines spontaneously and in only rare cases from cell lines after oncogenic virus infection. We have used a plasmid (pSV3gpt) containing both the SV40 early region encoding T antigen and the bacterial gene xanthine-guanine phosphoribosyl transferase (gpt) to achieve high efficiency morphological transformation and immortalization of primary human skin fibroblasts. Transfection of this plasmid into primary human skin fibroblasts derived from a normal individual, two Cockayne's syndrome patients, and an immuno-deficient patient and selection for the gpt gene resulted in an altered cell morphology and growth properties characteristic of previously described SV40-transformed cells. Transfected cultures subsequently senesced, entered crisis and in each case formed a rapidly growing culture. The high efficiency of immunortalization described here (four out of four cell strains) is in contrast to previously described procedures utilizing focal overgrowth. We suggest that the use of a dominant selectable marker linked to the SV40 early region increases the probability of establishing an immortal human cell line.     

Introduction and recovery of a selectable bacterial gene from the genome of mammalian cells.

The simian virus 40 (SV40)-pBR322 recombinant, pSV2, carrying the origin of SV40 replication and the gpt gene of Escherichia coli, has been stably introduced into Chinese hamster ovary hprt- cells. All gpt-transformed cell lines were found to contain one or more insertions of pSV2 sequences exclusively associated with high-molecular-weight DNA. Additional analyses showed that at least one integrated copy in each cell line retained an intact gpt gene and flanking SV40 sequences required for expression of xanthine-guanine phosphoribosyltransferase. Most cell lines contained pSV2 sequences which had integrated with partial sequence duplication. Upon fusion with COS-1 cells, a simian cell line permissive for autonomous pSV2 replication, most gpt-transformed cell lines produced low-molecular-weight DNA molecules related to pSV2. The majority of these replicating DNAs were indistinguishable from the original transfecting plasmid in both size and restriction enzyme cleavage pattern. In addition, the recovered DNA molecules were able to confer ampicillin resistance to E. coli and to transform mouse L cells and Gpt- E. coli to a Gpt+ phenotype. These studies indicate that all of the genetic information carried by this SV40-plasmid recombinant can be introduced into and retrieved from the genome of mammalian cells.     

Phenotypic changes and gene expression in human colon mucosal epithelial cells upon transfection of a SV40 DNA-GPT recombinant

Summary Phenotypic changes (increased longevity, decreased growth factor requirements, altered cell surface features, growth in semisolid agarose, and SV40 T antigen expression) suggesting in vitro transformation were displayed by human normal colon mucosal epithelial cells transfected with pSV3gpt, a pBR322 recombinant containing the SV40 “early” T antigen coding region and the dominant selectable marker bacterial gene, xanthine-guanine phosphoribosyltransferase. In contrast, control cultures which received neither DNA nor the recombinatn pSV2gpt (which is identical to pSV3gpt but lacks the SV40 T antigen region) were not phenotypically altered.     

Efficient repair of 8-oxo-7,8-dihydrodeoxyguanosine in human and hamster xeroderma pigmentosum D cells

The repair of the endogenous lesion 8-oxo-7,8-dihydrodeoxyguanosine (8-oxodG) was investigated in the nucleotide excision repair mutant xeroderma pigmentosum D (XPD), using human normal or transformed XPD fibroblasts and the Chinese hamster XPD cell line UV5. In vivo repair of 8-oxodG induced by hydrogen peroxide treatment and analyzed by high-performance liquid chromatography/electrochemical detection was normal in the XPD mutant fibroblasts XP15PV and GM434, as compared to normal human fibroblasts GM970, GM5757, and GM6114. Similar results were obtained with the human SV40-transformed XPD mutant cell line GM8207 in comparison to the control cell line GM637. Repair of 8-oxodG was even slightly (2-3-fold) but reproducibly increased in Chinese hamster XPD mutant UV5 cells, as compared to parental AA8 cells. This unexpected effect was reversed by transfection in UV5 cells of a wild-type XPD cDNA and confirmed in in vitro experiments in which a plasmid substrate containing a single 8-oxoG was repaired by UV5 cell extracts. The data show that repair of 8-oxodG is normal in XPD cells, thus indicating that the neurological complications of XPD patients may not be linked to in vivo accumulation of this lesion.     

Quantitative and molecular analyses of radiation-induced mutation in AS52 cells

pSV2gpt-Transformed and wild-type Chinese hamster ovary (CHO) cell lines have been used to study radiation-induced mutation at the molecular level. The transformant, designated AS52, was constructed from a hypoxanthine-guanine phosphoribosyl transferase (HPRT)-deficient CHO cell line and contains a single, functional copy of the Escherichia coli xanthine-guanine phosphoribosyl transferase (XPRT) gene (gpt) stably integrated into the Chinese hamster genome. AS52 and wild-type CHO-K1-BH4 cells exhibit similar cytotoxic responses to uv light and X rays; however, significant differences occur in mutation induction at the gpt and hprt loci. A number of HPRT and XPRT mutants which arose following irradiation were analyzed by Southern-blot hybridization. Most XPRT (21/26) and all HPRT (23/23) mutants induced by uv light exhibited hybridization patterns indistinguishable from their parental cell lines. In contrast, all XPRT (26/26) and most HPRT mutants (15/21) induced by X irradiation contained deletion mutations affecting some or all of the gpt and hprt loci, respectively. These results indicate that X rays induce predominantly deletion mutations, while uv light is likely to induce point mutations at both loci.     

Transformation of teratocarcinoma stem cells and fibroblasts with various vectors containing the Eco.gpt gene as a selection marker

Eco.gpt, which codes for xanthine guanine phosphoribosyltransferase (XGPRT), when placed under the control of SV40 early genes regulating sequences (pSV2gpt) selects transformed teratocarcinoma cells with a low efficiency. The SV40 promoter may not function efficiently in teratocarcinoma stem cells, as suggested by the fact that such cells do not support SV40 T antigen expression. We have tested whether one could change the efficiency of gpt as a dominant selective marker in transformation by several operations. (1) Deletion of 121 base pairs (bp) upstream the bacterial coding sequence gpt (pQS14) did not make any difference. (2) Replacement of the SV40 regulating sequences by the HSV tk regulating sequences (pQS15) resulted in ten times fewer transformants with PCC4 teratocarcinoma cells as well as with L cells. No XGPRT activity was detectable in cultures 48 h after transfection. (3) Reintroduction of the PvuII-HindIII SV40 fragment (which contains an enhancing sequence together with the origin of replication and the early promoter of the virus) into the pQS15 vector, either in 5' or 3' from tk-gpt composite gene (pQS20 and pQS22) allows selection of ten to twenty times more transfected PCC4 or L cells colonies and restores transient XGPRT activity upon transfection. Whatever the vector used, the transformation frequency of PCC4 teratocarcinoma cells remains ten times lower than that of L cells. It appears that the presence of the SV40 PvuII-HindIII fragment in the vector increases cell transformation even with PCC4 cells and that the low frequency obtained with pSV2pgt is likely not due to the use of the SV40 early promoter.(ABSTRACT TRUNCATED AT 250 WORDS)     

UV mutation spectra in cell lines from patients with Cockayne's syndrome and ataxia telangiectasia, using the shuttle vector pZ189.

We have used the SV40-based shuttle vector pZ189 to determine ultraviolet mutation spectra in SV40-transformed cell lines from two patients with Cockayne's syndrome (CS) and ataxia telangiectasia (AT). The shuttle vector was UV-irradiated, transfected into the cells and recovered two days later, after many rounds of replication had occurred. Plasmid DNA was used to transform indicator bacteria in which plasmids containing a mutation in the supF gene resulted in white colonies. Mutant plasmids were analysed both by agarose gels and by DNA sequencing. In contrast to published spectra for xeroderma pigmentosum cells, the types of mutation induced by UV mutation in the CS and AT cell lines were similar to each other and to published spectra for normal cell lines. There were however, some differences in the sequence distribution of the mutations.     

Isolation and partial characterization of virus-transformed cell lines representing the A, G and variant complementation groups of xeroderma pigmentosum

We have established viral-transformed, apparently permanent (immortalized) cell lines from diploid fibroblasts representative of normal and xeroderma pigmentosum (XP) A, G and variant individuals. The XP-G and XP-variant cells represent complementation groups not previously available as permanent lines. All the new permanent cell lines exhibit SV40 T-antigen expression. They are also aneuploid and have growth characteristics typical of viral transformants. They have retained the phenotypes of UV sensitivity, reduced repair synthesis or defective 'postreplication repair' appropriate to the XP complementation group they represent. Additionally, the new cell lines are all transfectable with the selectable plasmid pRSVneo. The XP-G and XP-variant cell lines show enhanced transfection with UV-irradiated plasmid DNA; a phenomenon previously reported for normal immortalized cells and for immortalized cells from the A and F complementation groups of XP.     

Host cell reactivation of CAT-expression vectors as a method to assay for cloned DNA-repair genes

We demonstrate the feasibility of using passive host-cell reactivation of a shuttle-vector pRSVcat to detect cloned DNA-repair genes. As models, a transient expression vector, pRSVdenV, and a positive-selection vector, pRSVdenV/SVgpt, were constructed containing the T4 coliphage denV gene, coding for an ultraviolet-specific endonuclease, under promotion of the Rous sarcoma virus (RSV) long-terminal repeat. Cotransfection of one or three copies of pRSVdenV per UV-irradiated pRSVcat molecule into xeroderma pigmentosum (XP) cells (XP12Ro[M1]) resulted in a dramatic increase in transient expression of chloramphenicol acetyl transferase (CAT) activity. XP clones stable transformed by pRSVdenV/SVgpt but not the parent cell line rescued CAT activity from this UV-irradiated reporter gene. The ability to express CAT activity from a UV-irradiated pRSVcat correlated with the presence of the structural denV gene as detected by Southern blot analysis. Post-UV irradiation colony-forming ability and DNA nucleotide excision-repair synthesis were partially restored in XP clones which rescued CAT activity. These results demonstrate the feasibility of using the cloned denV gene with its well characterized pyrimidine cyclobutane dimer-specific endonuclease activity to reconstitute UV-induced DNA repair in human cells deficient in DNA repair. Measuring CAT expression from pRSVcat affords a rapid, sensitive procedure to screen for functional cloned DNA-repair genes and to test mutant cells for defects in DNA repair.     

Enhanced induction of SV40 replication from transformed rat cells by fusion with UV-irradiated normal and repair-deficient human fibroblasts

Fusion of SV40-transformed rat (BRKSV) cells which do not spontaneously produce infectious virus, with permissive monkey cells resulted in a low level of production of infectious virus in the heterokaryons. UV-Irradiation of the BRKSV cells prior to fusion did not result in increased virus production, but irradiation of the monkey cells prior to fusion did result in enhanced induction (EI) of SV40, as compared to control experiments in which neither cell type was irradiated. This indicated that rat cells lack the ability to initiate replication of integrated SV40 upon UV-irradiation and do not contain "permissiveness" factors that are required to support SV40 replication. In contrast, monkey cells do contain such permissiveness factors which seem to be temporally enhanced by UV-irradiation, and thus may be responsible for the EI phenomenon. Expression of EI was dose-dependent and reached maximum values approximately 24 h after UV-irradiation. The kinetics of EI resembled that of EI previously established for SV40 induction in semi-permissive cells, and of enhanced reactivation (ER) and enhanced mutagenesis (EM) of SV40 in monkey cells. Similar kinetics of EI were obtained when human diploid fibroblasts were used for fusion with BRKSV cells. Similar levels of EI were found with normal human cells and repair-deficient xeroderma pigmentosum (XP) cells of complementation groups A and C, and XP variant cells. This suggests that expression of EI is not related to excision repair. Since EI is also normally expressed in XP cells which display an abnormal ER of HSV and in XP variant cells which show a delayed EM of HSV, we conclude that EI may occur independently of ER and EM. Finally it was shown that treatment of human cells with N-ethyl-N-nitrosourea results in similar induction of EI as irradiation with UV-light, and that addition of TPA in fusion experiments has no effect on EI.