A phenotypically and karyotypically stable human thyroid epithelial line conditionally immortalized by SV40 large T antigen.

Primary cultures of normal human neonatal thyroid follicular cells were transfected with a plasmid expressing a temperature-sensitive (tsA58) mutant of SV40 large T antigen. An epithelial cell line, designated B-thy-ts.1, was obtained which showed tight temperature-dependent growth. In sharp contrast to previous such lines, which were derived from adult thyroid, B-thy-ts.1 has retained a well-differentiated phenotype as reflected in its morphology and cytokeratin expression pattern. In addition to phenotypic stability the line also displays an unusually stable karyotype, lacking the usual clastogenic effects of SV40, which we speculate to result from a greater DNA repair capacity of its cell of origin. B-thy-ts.1 should be a particularly useful tool with which to study the effects of activated oncogenes on epithelial growth and differentiation.     

Neoplastic transformation of human keratinocytes by polybrene-induced DNA-mediated transfer of an activated oncogene

Polybrene, in conjunction with dimethyl sulfoxide (DMSO) shock has been shown to increase the frequency of DNA-mediated gene transfer to mammalian cells as compared with the frequency obtained with calcium phosphate transfection. We have successfully adapted this procedure for use with human epidermal keratinocytes. Non-tumorigenic human epidermal epithelial cells immortalized by SV40 tumor antigen were neoplastically transfected, using Polybrene at a concentration of 10 micrograms ml-1, followed by a 4 min shock, with 30% DMSO, with a plasmid carrying the activated H-ras gene from the EJ bladder carcinoma cell line. The transfected cells showed morphological alterations and induced carcinomas when transplanted into nude mice. They contained integrated copies of the transfected H-ras gene and expressed high levels of the p21 protein. Polybrene-induced DNA transfection, therefore, offers the opportunity to transfer genes effectively into human epidermal keratinocytes and should accelerate the study of the interaction between oncogenes and human epithelial cells. This study appears to represent the first neoplastic conversion of nontumorigenic, immortalized human epidermal keratinocytes by an activated human oncogene.     

Characterization of activated proto-oncogenes in chemically transformed syrian hamster embryo cells

The Syrian hamster embryo (SHE) cell transformation model has been used by many investigators to study the multistep process of neoplastic transformation induced by chemical carcinogens. In this study we have attempted to determine if activated proto-oncogenes are present in the transformed cells induced by a variety of chemical carcinogens. Twelve carcinogen-induced hamster cell lines, established by treatment of normal SHE cells with benzo[a]pyrene, diethylstilbestrol, or asbestos, were examined. One spontaneously transformed cell line (BHK-A) was also studied. Some of the cell lines were also tested for oncogene activation at the preneoplastic stage, before they acquired tumorigenic potential. DNAs from normal, preneoplastic, and neoplastic cells were tested by transfection into mouse NIH 3T3 cells, and morphologically transformed foci were scored on the contact-inhibited monolayer of 3T3 cells. The frequency of focus formation for normal SHE cell DNA was <0.0008 foci/μg DNA, while approximately 40% (5 of 12) of the DNAs from carcinogen-induced, tumorigenic hamster cell lines induced foci at a frequency of ? 0.012 foci/μg DNA. The other seven carcinogen-induced cell lines and the BHK-A cells were negative (<0.002 foci/μg DNA). When the DNAs from transformed foci induced by the five positive cell lines were retransfected into NIH 3T3 cells, the frequency of secondary foci of 3T3 cells was as much as 50-fold higher (1.34 foci/μg DNA) than with the primary transfectants. DNAs from transformed foci or tumors derived from transformed foci were screened by Southern blot analyses with known oncogenes and with a hamster repetitive DNA probe for the presence of transfected hamster oncogenes. Newly acquired hamster Ha-ras sequences were detected in transformed 3T3 cells induced by four of the five hamster tumor DNAs. Immunoprecipitation of lysates of several secondary transformants with a ras monoclonal antibody (Y13–259) showed altered gel mobility of the p21^ras protein consistent with a mutation at codon 12. These activated ras genes were detected by the NIH 3T3 assay in the tumorigenic hamster cells but not in the preneoplastic, immortal cell from which they were derived. The activated Ha-ras proto-oncogene was detected in cell lines induced by each of the three different carcinogens studied. Cells from transformed foci inauced by DNA from one of the hamster tumor cell lines (BP6T) contained hamster sequences but did not show newly acquired Haras, Ki-ras, or N-ras genes on Southern analysis or altered p21^ras protein. The transforming gene in this cell line appears to be a non-^ras oncogene. These observations indicate that ～40% of the chemically transformed Syrian hamster tumor cell lines have activated Ha-ras oncogenes. The activation of Ha-ras proto-oncogene is a late, postimmortalization step in the neoplastic progression of SHE cells. Only one cell line with a non-^ras oncogene was detected in the NIH 3T3 focus assay, and ～60% of the cell lines were inactive in this assay, indicating the need to develop alternative assay systems for oncogene activation. Some of the preneoplastic Syrian hamster cell lines may be useful for this purpose.     

Detection and identification of activated oncogenes in human skin cancers occurring on sun-exposed body sites

High-molecular-weight DNA isolated from eight fresh human skin cancers occurring on sun-exposed body sites were assayed for their ability to transform NIH 3T3 cells. A cotransfection protocol using pSV2-neo DNA, which confers resistance to the antibiotic G418, was used to select cells that had taken up the transfected DNA. About 2 weeks after transfection, G418-resistant colonies were pooled and injected s.c. into athymic nude mice. The NIH 3T3 cells transfected with DNA from six of the human skin cancers induced tumors in nude mice. DNAs from all six tumor cell lines contained human alu sequences. Southern blot hybridization with ras-specific probes revealed that DNAs from the four alu-rich tumors contained the human Ha-ras oncogene, in addition to that of the NIH 3T3 controls. In contrast, DNAs from the other two tumors did not contain any of the known oncogenes tested, except those endogenous to NIH 3T3 cells. DNAs from three of four first cycle tumorigenic transformants gave rise to morphologically transformed foci when assayed in a second cycle of transfection. DNAs from all three secondary transformants contained discrete human alu sequences, and in addition, contained Ha-ras sequences similar to those present in their respective primary transformants. Interestingly, DNA from both primary and secondary transformants of one particular human squamous cell carcinoma contained highly amplified copies of the Ha-ras oncogene. These results suggest that activation of the Ha-ras oncogene may be common in human skin cancers originating on sun-exposed body sites. Further characterization of the Ha-ras oncogenes present in these human skin cancers may provide information on the molecular mechanisms by which UV radiation of the sun induces human neoplasms on exposed body sites.     

Sensitization of transformed rat cells to parvovirus MVMp is restricted to specific oncogenes

The rat cell line FR3T3 was transformed with the retroviral oncogenes v-myc or v-src, with the DNA tumor viruses SV40 or bovine papilloma virus strain 1 (BPV-1) or with the 69% transforming region of BPV-1. The transformants were compared with the uncloned parental line for their susceptibility to the lytic effect and to the replication of MVMp, an autonomous parvovirus. Expression of v-myc and v-src proteins and of SV40 large T antigen correlated with a greater cell susceptibility to MVMp-induced killing. Thus, the expression of both cytoplasmic and nuclear oncogene products may sensitize rat fibroblasts to MVMp. In contrast, cell lines transformed by BPV-1, including highly tumorigenic and tumor-derived clones, were on the average as resistant as the parental cell line to MVMp infection. A similar resistance to MVMp-induced killing was displayed by BPV-1-transformed NIH3T3 cells. However, supertransformation of one of the BPV-1-transformants by the human EJ-Harvey ras-1 oncogene, known to sensitize FR3T3 and NIH3T3 cells, correlated with an increase in susceptibility to MVMp. Therefore, the failure of BPV-1 transformation to sensitize murine cells to parvoviral attack may be ascribed to the tumor virus rather than to the cells undergoing transformation. Hence, cell sensitization to MVMp appears to be oncogene-specific and cannot be taken as an absolute correlative with neoplastic transformation.     

Single-steep transformation of human breast epithelial cells by SV40 large T oncogene.

Normal human mammary epithelial cell (HMEC) cultures originating from 2 mammoplasty reduction surgical samples were transfected with replication-defective SV 40 DNA. Two independent cell lines designated as S2T2 and S1T3, selected for their increased proliferation potential and lifespan, were propagated for greater than 22 months in culture. They maintained a near-diploid karyotype with few chromosomal markers such as trisomy 1q (S1T3) and trisomy 8q (S2T2), which are most common in breast cancer in vivo. Immortalized S1T3 cells were not tumorigenic, whereas S2T2 cells produced slowly growing tumors in nude mice. One tumor was propagated in vitro and the transformed NS2T2 cell line subsequently raised 100% large tumors in the nude mouse. Rearrangement of the SV40 genome was observed in NS2T2 cells, which was not associated with increased expression of large T antigen. S1T3, S2T2 and transformed NS2T2 cell lines expressed cytokeratins CK18, CK19, the mammary-specific antigen DF3, and functional EGF receptors. Single-step immortalization and malignant transformation of human breast epithelial cells can thus occur upon transfection with SV40 large T oncogene. The chromosomal abnormalities observed in these cell lines suggest that they could offer a model for the study of breast-tumor progression in vitro.     

Neoplastic transformation of a human bronchial epithelial cell line by a recombinant retrovirus encoding viral Harvey ras

Activated ras oncogenes have previously been implicated in the pathogenesis of human lung carcinomas. A v-Ha-ras-containing retrovirus, Zip-ras, was generated by inserting the coding region of the v-Ha-ras oncogene into the Zip-NeoSV(X) [Cepko et al., Cell 37:1053-1062, 1984] retroviral vector. Amphotrophic Zip-ras retrovirus was used to infect an SV40 large T antigen-positive immortalized cell line, BEAS-2B, derived from normal bronchial epithelial cells, the predominant progenitor cells of human lung carcinomas. Zip-ras-infected BEAS-2B cells selected for G418 resistance formed anaplastic carcinomas in 12 of 15 athymic nude mice (latency 3 wk), whereas Zip-NeoSV(X)-infected BEAS-2B control cultures inoculated into 12 nude mice formed no tumors after a minimum of 7 mo. Tumor cell lines were established and demonstrated to be of human epithelial origin and to express v-Ha-ras p21 protein. A common feature of the tumor cell lines was an increase in ploidy. The increased efficiency of neoplastic transformation by v-Ha-ras of cell lines as compared with our previous results with normal bronchial epithelial cells [Yoakum et al., Science 227:1174-1179, 1985] is consistent with the hypothesis that the "immortalization" step is rate-limiting in in vitro human epithelial cell carcinogenesis.     

Timing of induction of tgf-alpha in ras induced human bladder neoplastic progression

Introduction of a H-ras oncogene into an SV-40 immortalized human urothelial cell lines (SV-HUC) results in morphologically altered cell clones which acquire tumorigenic potential following serial passaging in culture. Early and late passage cells, from individual ras transfected clones exhibiting different tumorigenic potential, display increased growth factor synthesis in mitogenic assays. Northern blot analysis revealed induction of TGF-alpha mRNA concomitant with the introduction of a H-ras oncogene with no modulation in EGF receptor expression observed throughout neoplastic progression. Consistent with completion of an autocrine loop, down modulation and activation of EGF receptors was observed in early passage cells coincident with TGF-alpha expression. In this human urothelial progression model TGF-alpha secretion follows the introduction of a H-ras oncogene prior to the acquisition of tumorigenic potential.     

Immortalization of human adult prostatic adenocarcinoma cells by human papilloma virus HPV16 and — 18 DNA

Primary prostate epithelial and prostate adenocarcinoma cells cultured in serum-free medium grew for up to 10 passages before senescence. Cells from prostate adenocarcinoma of a 55-year-old patient without lymph node involvement were transfected with plasmids containing recombinant human papilloma virus HPV16 or HPV18 DNA and the selectable neomycinresistance gene. After G-418 selection, cells underwent crisis, and surviving cells infected with retroviruses encoding the HPV18 E6/E7 genes (HPV-PAC1), transfected with a head-to-tail dimer of the complete HPV16 genome (HPV-PAC2), or transfected with HPV18 E6/E7 early genes (HPV-PAC3) were established. HPV-PAC1 and HPV-PAC2 cultures appeared morphologically similar to primary cultures even after 40 passages. However, HPV-PAC2 cultures had a clonal morphology. All lines were positive for cytokeratin 18, had acquired vimentin expression, and contained either HPV16 or HPV18 sequences integrated into host DNA. None was tumorigenic in nude mice or formed colonies in soft agar. These cells did not secrete prostate specific antigen nor respond to androgen although tamoxifen inhibited the growth of the cells. Immunohistochemistry showed no evidence of p53 overexpression. Further characterization of these cell lines and examination of their response to chemotherapeutic agents may provide relevant information for the study of hormone-independent PC.     

Human oncogenes detected by a defined medium culture assay

Oncogenes in DNAs from human tumor cell lines have been detected by a new transformation assay. Cellular DNAs are transfected into NIH3T3 murine fibroblasts, and transformed cells are selected by maintaining cell cultures in a defined medium lacking platelet-derived or fibroblast growth factors. DNAs from eight of 17 human tumor cell lines have yielded transformants by this method. Activated cellular ras genes account for three of the transforming activities. The SAOS2 osteosarcoma cell line contains an activated oncogene distinct from 18 known oncogenes. Another cellular oncogene was detected as the consequence of a fortuitous transfection-mediated DNA rearrangement.     

Different malignant phenotypes induced in a stable, subdiploid, benign epithelial clone by DNA transfection.

Progression to malignancy in carcinomas has been studied in a stable, benign, subdiploid, cloned epithelial cell line (A5P/B10) sensitive to Geneticin at 100 micrograms/ml. A total of 28 cell lines were selected for Geneticin - resistance and inoculated into the footpads of syngeneic animals following co-transfection with pSV2neo and genomic DNA, or transfection with plasmid constructs containing neo and the activated Ha-ras oncogene. The behavior of 12 cell lines cotransfected with normal genomic DNA and inoculated into 146 footpads was the same as the A5P/B10 cells. Low grade primary tumors were produced in 122 footpads by 13 cell lines transfected with Ha-ras, and a proportion (61/122) produced well-differentiated lymph node metastases. One of 3 cell lines cotransfected with genomic DNA from a malignant cell line (BC1) produced 8 anaplastic primary tumors with anaplastic metastases. Cell lines from lymph nodes involved by these anaplastic tumors were sensitive to Geneticin, and genomic DNA from 2 clones of these cells failed to produce a malignant phenotype when co-transfected into the A5P/B10 cells. These results indicated that the progression to a malignant phenotype induced in benign cells from a spontaneous epithelial tumor by co-transfection with genomic DNA from malignant cells was different from that induced by the ras oncogene.     

Normal cells and malignant cells transfected with the HRas oncogene have the same heat sensitivity in culture

Mouse embryo cells (C3H 10T1/2) were transfected with a plasmid (pAL8A) containing the HRas oncogene and neomycin resistance gene. Five transfected cell clones were isolated and established as cell lines, and these showed neomycin resistance. Two of these cell lines expressed a normal morphology while three showed a transformed morphology. Four of the cell lines produced tumours in nude mice. Flow cytometry measurements showed that exponentially growing cell cultures of the five transfected cell lines had the same cell cycle distribution as the normal parental cell line. The sensitivity to hyperthermia of the five transfected cell lines was the same as that of the normal cell line for temperatures ranging from 42.0 to 45.0 degrees C. Thus in these studies we found no difference in the thermal sensitivity of normal and malignant cells transfected by the Hras oncogene.     

Tumour perfusion and associated physiology: Characterization and significance for hyperthermia

Mouse embryo cells (C3H 10T1/2) were transfected with a plasmid (pAL8A) containing the HRas oncogene and neomycin resistance gene. Five transfected cell clones were isolated and established as cell lines, and these showed neomycin resistance. Two of these cell lines expressed a normal morphology while three showed a transformed morphology. Four of the cell lines produced tumours in nude mice. Flow cytometry measurements showed that exponentially growing cell cultures of the five transfected cell lines had the same cell cycle distribution as the normal parental cell line. The sensitivity to hyperthermia of the five transfected cell lines was the same as that of the normal cell line for temperatures ranging from 42.0 to 45.0°C. Thus in these studies we found no difference in the thermal sensitivity of normal and malignant cells transfected by the Hras oncogene.     

Frequent activation of non-ras transforming sequences in neoplastic Syrian hamster cells initiated with chemical carcinogens

Carcinogen-caused transformation of Syrian hamster embryo cells has been widely used as a model for experimental carcinogenesis. However, analysis of the molecular mechanisms of hamster cell transformation has been limited. To expand the understanding of the molecular basis of this system, 22 independently derived Syrian hamster neoplastic cell lines initiated with chemical carcinogens were screened for the presence of dominant transforming sequences by DNA transfection into mouse NIH3T3 cells. High molecular weight DNAs from 12 (55%) of these cell lines transformed NIH3T3 cells through serial transfection cycles. NIH3T3 transformants contained hamster-specific repetitive sequences, which co-segregated with the transformed phenotype in successive transfection rounds. Results from Southern hybridization analyses and p21ras mobility assays indicated the presence of N-ras oncogenes, presumably activated by point mutations at codon 61, in 3 of the 12 (25%) transfection positive lines, all initiated with sodium bisulfite; non-ras transforming sequences were apparently activated in the remaining 9 (75%) lines. DNA prepared from NIH3T3 transformants derived from cell line 81C39 was analysed by Southern hybridization with a battery of 38 probes including non-ras oncogenes known to score as positive in the NIH3T3 assay as well as other retroviral and mammalian oncogenes. Each probe hybridized to DNA fragments showing the mobility characteristic of NIH3T3 protooncogenes, but failed to detect homolog sequences of hamster origin, even under hybridization conditions which allowed their detection in hamster DNA. Results show that ras activation occurs at a low frequency in hamster neoplastic transformation and strongly suggest that novel transforming sequences are activated, thus validating the use of this system for investigating the role of non-ras transforming sequences in neoplasia.     

Transformation of normal homologous cells by a spontaneously activated Ha-ras oncogene

Several tumor-derived oncogenes have been shown to independently act as complete carcinogens following transfection into target cells from established tissue culture lines. However, the number and types of oncogenes required to transform primary cultures of normal mammalian cells is unclear. To clarify this issue in a simplified model system, we transfected genomic DNA from a naturally occurring rat tumor into NIH/3T3 cells as well as into early passage rat embryo fibroblasts. The 3T3 cells were transformed with high efficiency to malignant phenotypes; the rat embryo cells were transformed at lower frequencies following cotransfection with a selectable neomycin resistance marker and treatment with Geneticin (G418). The transformed rat cells had cancerous phenotypes as determined by in vitro, cytogenetic, and in vivo criteria. Moreover, the transformed mouse and rat cells contained new tumor DNA-derived nucleotide sequences homologous to the activated human Ha-ras oncogene. Elevated levels of Ha-ras-specific mRNA, as well as enhanced expression of the Mr 21,000 oncogene product, were detected in the transformed cells. Therefore, under well-defined experimental conditions, a spontaneously activated Ha-ras oncogene from a naturally occurring tumor was able to independently transform normal, homologous cells to a malignant phenotype.