Oncogenicity of DNA in vivo: Tumor induction with expression plasmids for activated H-ras and c-myc

All vaccines and other biological products contain contaminating residual DNA derived from the production cell substrate. Whether this residual cell-substrate DNA can induce tumors in vaccine recipients and thus represent a risk factor has been debated for over 50 years without resolution. As a first step in resolving this issue, we have generated expression plasmids for the activated human H-ras oncogene and for the murine c-myc proto-oncogene. Their oncogenic activity was confirmed in vitro using the focus-formation transformation assay. Two strains of adult and newborn immune-competent mice were inoculated with different amounts of either plasmid alone or with a combination of the H-ras and c-myc plasmids. Tumors developed only in mice inoculated with both plasmids and only at the highest amount of DNA (12.5 microg of each plasmid). The NIH Swiss mouse was more sensitive than the C57BL/6 mouse, and newborn animals were more sensitive than adults. Cell lines were established from the tumors. PCR and Southern hybridization analyses demonstrated that both inoculated oncogenes were present in all of the tumor-derived cell lines and that the cells in the tumors were clonal. Western analysis demonstrated that both oncoproteins were expressed in these cell lines. These results demonstrate that cellular oncogenes can induce tumors following subcutaneous inoculation. Such information provides a possible way of evaluating and estimating the theoretical oncogenic risk posed by residual cell-substrate DNA in vaccines.     

NIH/3T3 cells transfected with human tumor DNA containing activated ras oncogenes express the metastatic phenotype in nude mice.

NIH/3T3 cells transfected with DNA from malignant human tumors produced experimental and spontaneous metastases in nude mice. In contrast, parent or spontaneously transformed NIH/3T3 cells failed to metastasize. The transfected clones contained either activated c-Harvey-ras or N-ras oncogenes. A representative clone (T71-17SA2) which was used to assess selected cellular and host factors relevant to the metastatic process produced lung metastases in 100% of the NIH nude mice recipients, secreted augmented levels of type IV collagenase, and invaded human amnion basement membrane in vitro. Expression of the metastatic phenotype was not related to decreased sensitivity to natural killer cells or macrophage-mediated cytotoxicity. Analysis of the cellular DNA from the T71-17SA2 transfectant and its corresponding metastases, both of which contained activated N-ras oncogenes, revealed a twofold increase in the N-ras-specific DNA sequences in the metastatic cells. Thus, transfection with human tumor DNA containing activated ras oncogenes can induce the complete metastatic phenotype in NIH/3T3 cells by a mechanism apparently unrelated to immune cell killing.     

Thyrotropin receptor gene expression in oncogene-transfected rat thyroid cells: correlation between transformation, loss of thyrotropin-dependent growth, and loss of thyrotropin receptor gene expression.

Rat FRTL-5 and PC-Cl-3 thyroid cells are continuously cultured, clonal lines which require thyrotropin to grow and function. Both can be efficiently transformed when infected with RNA or DNA viruses carrying oncogenes or when directly transfected with activated oncogenes. Transformation, assayed by the appearance of cell growth in agar and by tumorigenicity in syngeneic rats or nude mice, is associated with the loss of thyrotropin-dependent cell division and thyrotropin-regulated functions such as thyroglobulin synthesis. In 16 clones of FRTL-5 or PC-Cl-3 cells transformed with different oncogenes, we show that loss of thyrotropin-dependent growth and function correlates with the loss of thyrotropin receptor gene expression, measured with a rat thyrotropin receptor cDNA probe.     

Immortalization by c-myc, H-ras, and Ela oncogenes induces differential cellular gene expression and growth factor responses.

Early-passage rat kidney cells were immortalized or rescued from senescence with three different oncogenes: viral promoter-driven c-myc, H-ras (Val-12), and adenovirus type 5 E1a. The normal c-myc and H-ras (Gly-12) were unable to immortalize cells under similar conditions. Quantitation of RNA in the ras-immortalized lines demonstrated that the H-ras oncogene was expressed at a level equivalent to that of the normal H-ras gene in established human or rat cell lines. Cell lines immortalized by different oncogenes were found to have distinct growth responses to individual growth factors in a short-term assay. E1a-immortalized cells were largely independent of serum growth factors, whereas c-myc-immortalized cells responded to serum better than to epidermal growth factor and insulin. H-ras-immortalized cells responded significantly to insulin alone and gave a maximal response to epidermal growth factor and insulin. Several cellular genes associated with platelet-derived growth factor stimulation, including c-myc, were expressed at high levels in the H-ras-immortalized cells, and c-myc expression was deregulated, suggesting that the H-ras oncogene has provided a "competence" function. H-ras-immortalized cells could not be morphologically transformed by secondary transfection with a long terminal repeat-c-myc oncogene, but secondary transfection of the same cells with H-ras (Val-12) produced morphologically transformed colonies that had 20- to 40-fold higher levels of H-ras oncogene expression. Thus, transformation in this system is dependent on high levels of H-ras oncogene expression rather than on the presence of activated H-ras and c-myc oncogenes in the same cell.     

Alterations in c-abl gene methylation in cells transformed by phagocyte-generated oxidants

DNA from 10T1/2 cells transformed by activated neutrophils was analyzed for restriction length polymorphisms (RFLPs) in cellular homologues of retroviral oncogenes, and consistent RFLPs were found in MspI sites of the c-abl gene of all PMN-transformed cell lines. MspI digests probed with c-myc, v-Ki-ras, v-Ha-ras or v-mos showed no RFLPs, and none were observed in EcoRI, PstI, HindIII, BamHI, SmaI, Sau3a, MboI, HhaI, or TaqI digests probed with v-abl. Analysis of HpaII digests supports the conclusion that c-abl RFLPs result from differential methylation of the CCGG HpaII/MspI recognition sequence. MspI RFLPs in the c-abl gene may provide markers for oxidant-related genetic injury.     

Pleiotropic mutants of NIH 3T3 cells with altered regulation in the expression of both type I collagen and fibronectin

Transformation of NIH 3T3 fibroblasts by v-mos causes a decrease in the levels of type I collagen RNA. In NIH 3T3 cells that have been made resistant to G418 by transfection with a plasmid in which the mouse alpha 2(I) collagen promoter is linked to the neo gene, subsequent v-mos transformation causes a loss of G418 resistance. After mutagenesis of these v-mos-transformed cells, G418-resistant colonies were selected. Two of these G418-resistant mutants showed an increased expression of the neo gene and of the endogenous type I collagen and fibronectin genes, without changes in their levels of v-mos RNA or in their ability to induce tumors. The mutations might alter cellular trans-acting factors that either directly or indirectly control the expression of the type I collagen and fibronectin genes in transformed cells.     

The effect of transfection with the oncogenes H-ras and c-myc on the radiosensitivity of a mink epithelial cell line.

We have investigated the effect of transfection with the oncogenes c-myc and H-ras on cellular radiosensitivity. We obtained a mink lung epithelial line, Mv1Lu (ATCC CCL-64), and two sublines which had been transformed by transfection with c-myc and mutated (T24) H-ras 1. The cell survival parameters do not differ significantly between the three lines. These parameters were, for the parent line: D0 = 1.95 Gy, n = 2.0; for the c-myc transfected line: D0 = 2.10 Gy, n = 2.33; and for the H-ras transfected line: D0 = 2.40 Gy, n = 1.77. Although the terminal slope of the survival curve of the cells of the parent line is slightly steeper than that for the cells of either of the transfected lines, the differences are not significant. Nor is there any difference between the cell lines at the clinically relevant dose of 2 Gy. We conclude that neither activated H-ras nor c-myc oncogenes alter the radiosensitivity of the Mv1Lu line.     

Identification of drm, a novel gene whose expression is suppressed in transformed cells and which can inhibit growth of normal but not transformed cells in culture.

Using differential display analysis, we compared the expression of RNA in v-mos-transformed cells and their flat revertant and isolated a novel gene, drm (down-regulated in mos-transformed cells), whose expression is down-regulated in parental v-mos-transformed cells but which is expressed at a high level in the revertant and normal rat fibroblasts (REF-1 cells). Analysis of different oncogene-transformed cells revealed that drm gene expression was also suppressed in REF-1 cells transformed by v-ras, v-src, v-raf, and v-fos. The drm cDNA contains a 184-amino-acid-protein-encoding open reading frame which shows no significant homologies to known genes in DNA databases. Polyclonal antibodies raised against drm peptide detect a protein with the predicted size of 20.7 kDa in normal cells and under nonpermissive conditions in cells conditionally transformed by v-mos but not in parental v-mos-transformed cells. Northern analysis of normal adult tissues shows that drm is expressed as a 4.4-kb message in a tissue-specific manner, with high expression in the brain, spleen, kidney, and testis and little or no expression in the heart, liver, and skeletal muscle. In situ hybridization analysis in adult rat tissue reveals good correlation with this pattern and indicates that drm mRNA is most highly expressed in nondividing and terminally differentiated cells, such as neurons, type 1 lung cells, and goblet cells. Transfection of a drug-selectable drm expression vector dramatically reduced the efficiency of colony formation in REF-1 and CHO cells, and the drm-transfected REF-1 survivors expressed low or nondetectable levels of exogenous drm mRNA. The toxic effects of drm can be overcome by cotransfection with constructs expressing oncogenic ras; furthermore, cells expressing high levels of drm and conditionally transformed with mos-expressing Moloney murine sarcoma virus rapidly undergo apoptosis when shifted to the nonpermissive temperature. Taken together, our data suggest that cells expressing high levels of drm undergo apoptotic death in the absence of oncogene-induced transformation and that drm represents a novel gene with potential roles in cell growth control or viability and tissue-specific differentiation.     

Changes in surface relief of suspended cells are morphological signs of the initial stage of neoplastic transformation in fibroblastic monolayer cultures.

The percentages of cells with different types of cell surface relief were determined in cell suspensions derived from monolayer cultures. Primary cultures of rat embryo fibroblasts (REF) and cell lines REF (LT) and REF-1, immortalized cells of which preserved normal phenotypic characteristics of the initial primary culture REF, as well as morphologically transformed tumorigenic lines REF (LT) ras and REF-2EJ were studied. In REF suspensions the cells with the blebbed type of surface relief were shown to be predominant as compared with those with microvillus relief whereas cell suspensions derived from both immortalized and fully transformed cultures display the reverse ratio of cells with those types of surface relief. Therefore, the pattern of cell surface relief in cell suspensions derived from fibroblastic monolayer cultures may serve as a morphological marker of the initial stage of neoplastic transformation-immortalization when typical morphological signs of cell transformation are not yet manifested in monolayer cultures.     

C127 cells resistant to transformation by tyrosine protein kinase oncogenes

C127 is a nontumorigenic mouse cell line widely used in in vitro transformation assays due to its normal morphological appearance and its very low levels of spontaneous transformation. We now report that C127 cells are resistant to transformation by tyrosine protein kinase oncogenes derived from growth factor receptors such as the retroviral v-fms and the human trk transforming genes. In contrast, these cells could be efficiently transformed by members of the ras oncogene family and by serine/threonine kinase oncogenes such as v-mos and v-raf. C127 cells were also found to be resistant to transformation by v-src, the prototype of a large family of tyrosine protein kinase oncogenes whose products are associated with the inner side of the plasma membrane. However, morphologically normal C127 cells expressing pp60v-src acquired a transformed phenotype upon continuous passage in vitro. Somatic cell hybrids (neoR, hygroR) obtained by fusion of G418-resistant C127 cells expressing p70trk (neoR) and hygromycin-resistant NIH3T3 cells (hygroR) exhibited transformed properties as determined by their ability to grow in semisolid agar. In contrast, no such growth was observed when these neoR p70trk-containing C127 cells were fused to control hygroR C127 cells. These results indicate that C127 cells may either lack or express insufficient levels of certain critical substrate(s) necessary for the onset of transformation by tyrosine protein kinase oncogenes.     

Methionine metabolism defect in cells transfected with an activated HRAS1 oncogene

Methionine dependence is a metabolic defect characterized by the inability of eukaryotic cells in culture to proliferate in a medium where methionine has been replaced by its immediate metabolic precursor, homocysteine. This defect has been reported to be a specific property of diverse tumour-derived and transformed cell lines; normal cell strains grow well under the above culture conditions. The basis of methionine requirement in such cells is not known. We asked whether this defect might be controlled by activated oncogenes and in particular by the mutated (activated) HRAS1 oncogene derived from the EJ/T24 human carcinoma line. We report that this oncogene induces methionine requirement after transfection in non-transformed immortalized rat cells.     

Specific activation of the cellular Harvey-ras oncogene in dimethylbenzanthracene-induced mouse mammary tumors.

Genomic DNAs from dimethylbenzanthracene-induced BALB/c mouse mammary tumors arising from the transplantable hyperplastic outgrowth (HPO) line designated DI/UCD transformed NIH 3T3 cells upon transfection. Transforming activity was attributed to the presence of activated Harvey ras-1 oncogenes containing an A----T transversion at the middle adenosine nucleotide in codon 61. DNAs from untreated DI/UCD HPO cells and radiation-induced and spontaneous mammary tumors from the DI/UCD HPO line failed to transform NIH 3T3 cells. The results indicated that the mutation activation of Harvey ras-1 oncogenes was specific to dimethylbenzanthracene treatment in the mouse mammary tumor system.     

mos gene transforming efficiencies correlate with oocyte maturation and cytostatic factor activities.

The mos proto-oncogenes from different vertebrate species transform mouse NIH 3T3 cells with markedly different efficiencies. v-mos, mouse (c-mosmu), and chicken (c-mosch) mos transform NIH 3T3 cells 10- to 100-fold more efficiently than do human (c-moshu) and Xenopus (c-mosxc) mos. The mos genes with the highest transforming activity efficiently induce maturation in Xenopus oocytes and mimic cytostatic factor (CSF) by causing mitotic cleavage arrest in embryos. Chimeric v-mos/c-moshu proteins that had high transforming efficiencies in NIH 3T3 cells were also effective in the induction of oocyte maturation and CSF cleavage arrest. We measured the in vitro autophosphorylation activities of the different mos proteins and found that the levels of kinase activity of v-mos, c-mosmu, and c-mosch were much higher than that of c-mosxc. These data indicate that mos gene transforming efficiency and the ability to induce oocyte maturation or mimic CSF activity are correlated with in vitro autophosphorylation activity and suggest that the mos protein plays a similar role in transformed cells and normal oocytes.     

Model systems of carcinogenesis in vitro: the interaction of the ras oncogene with immortalized cells

Gene transfer experiments have shown that ras effector functions are sufficient to transform cells from a variety of established lines (e. g., mouse NIH3T3 cells). In contrast, primary cells and early passage rodent cells can be transformed by ras oncogenes only at low frequencies, unless cotransfected with collaborating genes such as adenovirus early region IA (EIA) or myc retroviral oncogene homologue. Primary rat embryo fibroblasts (REF) were chosen as a model for the analysis of multistep cellular transformation. Transfection of REF, immortalized by early region of simian adenovirus SA7 with c-Ha-ras oncogene cannot induce their morphological transformation. This phenomenon is observed only after second transfection with the same oncogene. These different cell lines can be used for further analysis of the mechanisms of carcinogenesis.     

Human cell transformation in the study of sunlight-induced cancers in the skin of man

Human cell transformation provides a powerful approach to understanding--at the cellular and molecular levels--induction of cancers in the skin of man. A principal approach to this problem is the direct transformation of human skin cells by exposure to ultraviolet and/or near-UV radiation. The frequency of human cells transformed to anchorage independence increases with radiation exposure; the relative transforming efficiencies of different wavelengths implies that direct absorption by nucleic acids is a primary initial event. Partial reversal of potential transforming lesions by photoreactivation suggests that pyrimidine dimers, as well as other lesions, are important in UV transformation of human cells. Human cells can also be transformed by transfection with cloned oncogenes, or with DNAs from tumors or tumor cell lines. Cells treated by the transfection procedure (but without DNA) or cells transfected with DNAs from normal mammalian cells or tissues show only background levels of transformation. Human cells can be transformed to anchorage-independent growth by DNAs ineffective in transformation of NIH 3T3 cells (including most human skin cancers), permitting the analysis of oncogenic molecular changes even in tumor DNAs difficult or impossible to analyze in rodent cell systems.     

Activity of topoisomerase I and endonucleases in cells transfected by a ras oncogene

Activities of nuclear endonucleases and topoisomerase I were measured in rat fibroblasts which were at the stages of tumor transformation: control embryonal fibroblasts--CEF; cells immortalised by transfection of S1A segment of SA7 adenovirus--REF-1; intermedius cells transfected once by EJras oncogene--REF-1EJ; and cells transformed after the second transfection by the same oncogene--REF-2EJ. The topoisomerase I and Ca2+, Mg2+-dependent endonuclease was most decreased at the stage of immortalised cells, and the intermedius stage (REF-1EJ) was characterized by the lower activity of Ca2+, Mg2+-dependent endonuclease. The highest activity of Mn2+-dependent endonuclease is seen in REF-2EJ cells. In model experiments the ability of Ca2+, Mg2+-dependent endonuclease to split non-stochastically the EJras oncogene inserted into pBR322 plasmid was shown. The role of the investigated enzymes in the restriction of plasmid integration, cellular immortalisation and recombination of plasmids with chromosomes during cell transformation is discussed.     

p53‐mediated regulation of cell cycle progression: Pronounced impact of cellular microenvironment

Data on the biological effects of some overexpressed oncogenes and their cooperation with cellular factors are, at least partially, contradictory. There are reports on the strong pro‐apoptotic action of temperature‐sensitive (ts) p53^135val in transformed cells at permissive temperature. However, in our experience very high levels of p53^135val induce in transformed rat cells at permissive temperature cell cycle arrest but not apoptosis. Comparison of the experimental protocols reveals that cells used for transfection strongly differ. Therefore, we decided to explore the impact of primary cells used for generation of cell clones on the biological effects evoked by p53 and c‐Ha‐Ras. In the present study, we used primary rat cells (RECs) isolated from rat embryos of different age: at 13.5 gd (y) and 15.5 gd (o). We immortalized rat cells using ts p53^135val mutant and additionally generated transformed cells after co‐transfection with oncogenic Ras. The RECs were transfected with a constitutively activated Ha‐Ras protein, a mutation that is found in a wide variety of human tumors. The ts p53^135Val mutant, switching between wild‐type (wt) and mutant conformation, offers the possibility to study the escape from p53‐mediated cell cycle control in a model of malignant transformation in cells with the same genetic background. Surprisingly, the kinetics of cell proliferation at non‐permissive temperature and that of cell cycle arrest at 32°C strongly differed between cell clones established from yRECs and oRECs, thereby indicating that overexpression of genes such as ts p53^135Val mutant and oncogenic‐Ha‐Ras does not fully override the intrinsic cellular program. J. Cell. Physiol. 219: 459–469, 2009. © 2009 Wiley‐Liss, Inc.