Cell division is required for expression of v-myc transforming properties in chicken embryonic neuroretina cells.

We previously reported that avian retroviruses carrying the v-myc oncogene alone fail to induce sustained proliferation and transformation of non-dividing chicken neuroretina (CNR) cells from 7-day-old embryos. However, v-myc is capable of transforming CNR cells which have been induced to multiply by the v-mil oncogene. These results suggest that entry into the cell cycle is required for the transformation of CNR cells by v-myc. To further assess the role of cell division, we investigated the transforming properties of v-myc in CNR cells conditionally induced to divide by the v-src gene or by modified culture conditions. We show that v-myc transforms CNR cells infected with Rous sarcoma virus mutants which induce cell proliferation in the absence of transformation. Expression of these transforming properties in CNR cells infected with temperature-sensitive v-src mutants depends on the continuous mitogenic activity of p60v-src. We also report that v-myc is able to transform CNR cells and to increase their growth potential under culture conditions which allow transient multiplication of uninfected cells. However, these v-myc-transformed cells rapidly cease to divide when returned to culture conditions that restrict the growth of normal cells. Taken together, these results indicate that transformation of CNR cells by the v-myc oncogene continuously depends on their ability to enter the cell cycle.     

The v-abl, c-fms, or v-myc oncogene induces gamma radiation resistance of hematopoietic progenitor cell line 32d cl 3 at clinical low dose rate

A variety of viral and cellular oncogenes have been described with differing mechanisms of action but with the common property of inducing morphologic alteration of cells in culture. Subclonal lines of oncogene expressing cells have been shown to produce tumors in vivo. Expression of the N-ras oncogene in embryo fibroblast NIH/3T3 cells has been demonstrated to increase radioresistance in vitro, and these results have been confirmed and extended to human cell lines expressing the c-raf oncogene. In the present report, we have examined the effects of expression of the c-fms, v-abl, or v-myc oncogene in a clonal hematopoietic progenitor cell line 32D cl 3. The 32D cell line is nonmalignant in vivo and is dependent upon a source of Interleukin-3 (IL-3) for growth in vitro. The radiation survival of 32D cl 3 cells transfected and expressed in the c-fms oncogene showed significant increase in the radioresistance at both 5 cGy/min and 116 cGy/min. A clone of 32D cl 3 transfected and expressing the v-myc oncogene demonstrated increased radioresistance at both dose rates. Results of split dose experiments suggested significant repair of sublethal irradiation damage of 32D-v-abl cells. Results were compared with expression of the same v-abl oncogene in the NIH/3T3 embryo fibroblast cell line. The data demonstrate that gamma irradiation resistance is significantly increased by each oncogene expressed in 32D cl 3 cells. The data on cell line 32D cl 3 may correlate with the radioresistance of v-abl expressing human hematopoietic cell malignancies treated by irradiation therapy.     

Antigens expressed on NIH 3T3 cells following transformation with DNA from human pancreatic tumor

This report documents that the pancreatic adenocarcinoma cell line, HPAF, contains oncogene activity detected by transformation of NIH 3T3 cells through transfection with HPAF DNA. The HPAF transfected NIH 3T3 cells do not contain oncogenes homologous with c-H-ras, c-K-ras, c-N-ras, v-fms, c-myb, c-sis, v-fgr, c-mos, c-myc, c-fos, v-fes, v-src, v-erb A, v-erb B, c-N-myc, v-raf, or v-abl, other than the endogenous mouse genes. The transfectants do express proteins detected by two-dimensional sodium dodecyl sulfate-polyacrylamide gel electrophoresis which were not found in nontransfected NIH 3T3 cells. Monoclonal antibodies raised against the transfectants recognize proteins not found in untransfected NIH 3T3 cells that are antigenically identical to proteins found in the HPAF cells. These antigens are also detected on six other human pancreatic adenocarcinoma cell lines but show a much more restricted distribution on lymphoblastoid, melanoma, prostatic carcinoma, and normal skin fibroblast cell lines.     

Transformation of NIH3T3 cells by Rous sarcoma virus occurs with high efficiency in the absence of proviral rearrangements or amplification.

NIH3T3 cells could be transformed by a mammaltropic strain of Rous sarcoma virus (RSV) with an efficiency 10(3) times greater than that observed in Balb/c 3T3 cells or other mammalian cell lines and almost identical to that of chick embryo fibroblasts. In infected NIH3T3 cells a single, properly integrated, provirus was sufficient to induce focus formation; moreover, kinase activity of pp60v-src and tyrosine phosphorylation of cellular proteins could be detected very soon after infection in the majority of cells. On the other hand, in transformed foci from RSV-infected Balb/c 3T3 cells both rearrangements and amplification of proviral sequences were frequently detected. Accordingly, expression of pp60v-src and ensuing tyrosine phosphorylation of cellular proteins occurred, at high levels, only in a minority of the infected cells. Furthermore, by using a murine retrovirus carrying the v-src oncogene and an independent selectable marker, we found that Balb/c 3T3 cells were transformed with a 100-fold lower efficiency than NIH3T3 cells, yet the majority of infected untransformed Balb/c 3T3 cells expressed active pp60v-src. These findings are consistent with the existence in most mammalian cell lines of a major restriction to v-src-induced transformation, operating at the level of proviral expression, that is apparently absent in NIH3T3 cells.     

Molecular analysis of DNA isolated from the different stages of x-ray-induced transformation in vitro

A major challenge in radiation carcinogenesis is to identify the cellular gene or genes involved in initiating the process. We examined the transforming activities of DNAs obtained from C3H10T1/2 cells during x-ray-induced morphological transformation. DNAs extracted from mass cultures of 10T1/2 cells at different times after irradiation with 600 rad and from type III-transformed foci were transfected into NIH 3T3 cells. The results indicate that certain oncogenes are activated beginning 3 wk after irradiation, well before the appearance of macroscopically visible transformed foci. For DNA isolated from x-ray-transformed 10T1/2 cells (type III foci), the frequencies of transfection were 0.003-0.11 foci/microgram of genomic DNA with NIH 3T3 cells and 0.004-0.04 foci/microgram genomic DNA using 10T1/2 cells as recipients. Southern blot analysis of DNAs obtained from 23 primary transfectants and from 23 x-ray-transformed cell lines indicated no gross rearrangements or amplification of any of the 14 oncogenes screened (v-Ha-ras, v-Ki-ras, N-ras, v-myc, v-raf, v-src, v-fes, v-abl, v-mos, v-erbA, v-erbB, v-myb, v-fos, v-sis). This suggests that x-irradiation may activate as yet unidentified oncogenes. The occurrence of positive transfection 3 wk after irradiation is discussed in terms of the hypothesis that transformation may not occur as a direct consequence of the exposure to x-rays but develops as a rare event in the progeny of the irradiated cells at some later time, as a consequence of the delayed activation of certain genes.     

Induced p21WAF1 expression acts to reverse myc myelomonocytic cell transformation

Two murine myelomonocytic cells lines were used to examine p21WAF1 expression in myc-induced cell transformation. tEMmyc4 and FDLV are two v-myc-transformed immortalised myeloid cell lines exhibiting different transformed phenotypes. FDLV cells were derived from the transduction of v-myc into FDC-P1 cells and retain growth factor (IL-3) dependence, whereas tEMmyc4 cells were derived from the transduction of embryonal monocytes with v-myc and are growth factor-independent, constitutively express endogenous CSF-1, and are highly tumorigenic in syngeneic mice. Both cell lines were found to exhibit low p21WAF1 expression. When examined in tEMmyc4 cells, neither the p53-dependent pathway (mitomycin C or exogenous p53) nor p53-independent pathway (TPA or growth factor, CSF-1, stimulation) acted to increase p21WAF1 levels. Growth factor (IL-3) withdrawal, shown to reduce p21WAF1 levels in parental FDC-P1 cells, failed to do this in FDLV cells. The dependence of p21WAF1 expression on v-myc was further demonstrated by showing that a v-myc-targeted ribozyme, which acts to decrease v-myc RNA, increased p21WAF1 levels in tEMmyc4 cells. Enforced expression of exogenous p21WAF1 in tEMmyc4 cells with dysfunctional growth cycle (including growth arrest and increased susceptibility to apoptosis) was examined. p21WAF1 partially restored cell cycle regulation and apoptosis as well as inhibited the delayed cell cycle progression and apoptosis induced by mitomycin C or serum withdrawal. These results show p21WAF1 expression to be affected by v-myc and a restoration of p21WAF1 expression to partially reverse myc-mediated transformation.     

Sensitivity pattern of normal and Ha-ras transformed NIH3T3 fibroblasts to antineoplastic drugs

Ha-ras-transformed NIH3T3 fibroblasts were compared with the parental cell line to investigate the influence of the Ha-ras oncogene on cellular chemosensitivity to antineoplastic drugs. Four NIH3T3 cell clones independently transformed by the Ha-ras oncogene, activated by mutation or overexpression, were analyzed: 3 clones were obtained by transfection of NIH3T3 cells with a mutation-activated Ha-ras gene and 1 clone by transfection of a large copy number of the normal Ha-ras proto-oncogene. Chemosensitivity of the transformed clones and of the parental cell line was analyzed when cells were in the same condition of proliferative activity and cell cycle phase distribution. No significant differences in chemosensitivity were observed between transformed and untransformed cell lines to doxorubicin, VP-16, cis-platinum or mitomycin C. Therefore, data suggest that activated Ha-ras oncogenes have no role in sensitivity to these antineoplastic agents.     

Trisomy of chromosome 9q: specific chromosome change associated with tumorigenicity during the process of X-ray-induced neoplastic transformation in golden hamster embryo cells

We have reported that trisomy of chromosome 7 is commonly observed in anchorage-independent clones isolated from X-irradiated golden hamster embryo cells. All 10 clones derived from different irradiated populations showed tumorigenicity when 1 x 10(7) cells were injected s.c. into nude mice (BALB/c, nu/nu). From karyotypic analysis, we found that 8 of 10 cells showed trisomy of chromosome 9. One cell line had a translocation between chromosomes 9q and 19q and trisomy of chromosome 7. The other cell line contained trisomy of chromosome 9 and a translocation between chromosomes 7q and 8q. Using Southern blot analysis, we observed no amplification of v-myc, v-Ha-ras, v-Ki-ras or N-ras-related oncogenes. Furthermore, we could not detect either an increase in expression of v-myc- and v-Ha-ras-related genes or the activation of any oncogene, by the NIH 3T3 transfection assay. Our results suggest that trisomy of chromosome 7 is insufficient for the expression of tumorigenicity and that increased dosage of chromosome 9q may play an important role in the malignant progression of X-ray-induced neoplastic transformation.     

Colon carcinoma K-ras 2 oncogene of a familial polyposis coli patient

The DNA of a colon carcinoma-derived cell line (KMS-4) and that of skin fibroblasts from a familial polyposis coli patient were transfected into NIH3T3 cells in order to detect oncogenes associated with the disease. No transformation was observed with the normal skin fibroblast DNA, while the KMS-4 cell DNA was able to transform NIH3T3 cells. Through hybridization with known oncogene probes, the KMS-4 transforming gene was found to be a human activated c-K-ras 2 oncogene. Sequence analysis of the molecularly cloned KMS-4 c-K-ras 2 oncogene showed a single nucleotide transition from G to T at the 12th codon. This results in substitution of cysteine for glycine at this position. On using labeled synthetic oligonucleotides to detect the mutation in codon 12, we found the G to T transition in colon carcinoma cells. This suggests that activation of the c-K-ras 2 oncogene could be associated with colon carcinoma induction.     

Resistance to apoptosis induced by alkylating agents in v-Ha-ras-transformed cells due to defect in p53 function

In this study, we examined the susceptibility of various oncogene-transformed NIH/3T3 cells to apoptosis induced by alkylating agents. Only v-Ha-ras-transformed cells showed marked resistance to apoptotic death induced by these drugs. Upon treatment with methylmethane sulfonate (MMS), NIH/3T3 cells exhibited normal G₁ checkpoint function accompanied by the accumulation of p53 and p21^CIP1/WAF1 protein. However, no such effects were observed in v-Ha-ras-transformed cells. To further examine the functional status of p53 in ras-transformed cells, we determined the DNA sequence, protein half-life, protein-complexing activity, and specific DNA-binding activity of p53. The results showed that ras transformants and parental NIH/3T3 cells had the same p53 protein half-life of 40 min or less, the same normal wild-type p53 cDNA sequence, and the same co-immunoprecipitable cellular proteins complexed with p53. In electrophoretic mobility gel-shift assays, however, nuclear extracts of cells treated with MMS, ras-transformed cells, and normal cells displayed distinct patterns of binding between p53 ad its consensus binding site. Furthermore, western blot analysis showed that the bcl-2 and bax proteins were constitutively elevated in ras-transformed cells but not in parental NIH/3T3 cells. Heat-shock protein 70 (hsp70), which has been found to be negatively regulated by wild-type p53, was also dramatically induced in ras-transformed cells but not in NIH/3T3 cells in response to MMS. Thus, our data suggest that an activated ras oncogene can suppress alkylating agent-induced apoptotic cell death by means of a defect in the signal transduction pathway regulating p53 function and alteration in the expression of apoptotic (bax) or anti-apoptotic proteins (bcl-2 and hsp70). Mol. Carcinog. 18:221–231, 1997. © 1997 Wiley-Liss, Inc.     

A mutant cell line derived from NIH/3T3 cells: two oncogenes required for in vitro transformation

EK-3, a cell line derived from NIH/3T3 cells, was isolated. These cells are nontumorigenic to NIH Swiss nude mice. They required both myc and ras genes for in vitro transformation in contrast to NIH/3T3 cells, which are efficiently transformed following transfection by ras alone. Two other genes, chloramphenicol acetyl transferase and geneticin resistance, could be efficiently transfected and expressed in both EK-3 cells and the parental NIH/3T3 cells. Thus the possibility that the requirement of myc in EK3 cells is due to low efficiency of transfection could be ruled out. The present study suggests that myc plays a significant role in the overall process of transformation rather than simply immortalization of the cells. The EK-3 line can be very helpful in elucidating this function.     

Effects of ouabain on NIH/3T3 cells transformed with retroviral oncogenes and on human tumor cell lines

Both murine and human cell lines transformed by the v-Ki-ras gene have been shown to be much more sensitive to the toxic effects of the cardiac glycoside ouabain than their respective controls. This differential toxicity has previously been used in the isolation of flat revertant clones from populations of Kirsten murine sarcoma virus transformed NIH/3T3 cells. Here, we have undertaken a further characterization of this phenomenon in murine and human tumor cells. Two different techniques, a 51Cr-release assay and a quantitative Crystal violet elution assay, have been employed to compare the sensitivities to ouabain of normal and v-Ki-ras-transformed NIH/3T3 cells. In each assay, ras-transformed NIH/3T3 cell lines displayed an increased sensitivity to ouabain as compared to the parental NIH/3T3 cell line, both in dose-response and in time-course experiments. In a separate study, ouabain was also able to inhibit the growth in semi-solid medium of 2 v-Ki-ras-transformed NIH/3T3 cell lines (DT and K-NIH) in a dose-dependent fashion. The same concentrations of ouabain were effective in both the 51Cr-release and Crystal violet assays. To address the question of whether increased sensitivity to ouabain is a specific result of transformation with the ras oncogene or is a common event which accompanies transformation by other oncogenes, we have screened a variety of transformed NIH/3T3 derivatives. All of these lines displayed an increased sensitivity to ouabain when compared to the parental NIH/3T3 cell line.     

Sensitization of human keratinocytes to killing by parvovirus H-1 takes place during their malignant transformation but does not require them to be tumorigenic

To investigate the antineoplastic activity of parvoviruses, proliferating normal human epidermal cells and a series of established keratinocyte cell lines derived from squamous cell carcinomas or transformed in vitro, were compared for the outcome of H-1 virus infection. All established keratinocyte cell lines were more sensitive to killing by H-1 virus than normal epidermal cells, although to varying extents. Using a step-wise procedure for malignant transformation in vitro, we found that sensitization of transformed epidermal cells to H-1 virus can be dissociated from the acquisition of a tumorigenic phenotype. Thus, spontaneously- or SV40-immortalized human keratinocytes were moderately and highly sensitive to H-1 virus, respectively, and could be made tumorigenic by Harvey-ras oncogene transfection without a major change in their susceptibility to the virus. The capacity of human keratinocytes for replicating and expressing H-1 virus DNA appears to be a revealer of cellular alterations that take place in at least some pathways to malignant transformation but that may be insufficient to confer a tumorigenic potential.     

Relationships between heparanase activity and increasing metastatic potential of fibroblasts transfected with various oncogenes

We have examined the effects of transformation by activated H-ras and other transforming oncogenes on the activity of the enzyme, heparanase. Degradation of 3H-N-acetylated-partially N-desulfated heparan sulfate by cellular extracts of the transformants was assessed by gel permation chromatography. More extensive degradation was observed with 10T1/2 mouse embryo fibroblasts transfected with an activated H-ras oncogene. The cells having the highest metastatic potential (CIRAS-3) were shown to contain the greatest heparanase activity, giving 49% higher levels of activity than parental cells (P less than 0.0002). Furthermore, the enzyme activity produced by a series of H-ras transformed cell lines increased progressively with metastatic potential (non-parametric rank correlation coefficient r = 0.96). Transfection of NIH 3T3 fibroblasts with activated H-ras, v-src or v-fes oncogenes, which induced the metastatic phenotype, did not lead to large increases in heparanase activities. Also, inhibition of ras-induced malignancy by cotransfection of rat REF cells with the Ad2 E1a oncogene did not produce significant declines in heparanase activities. These results are consistent with the view that modifications in heparanase activity can play a role in the complex process of metastasis in some, but not all situations.     

Inhibition of H-ras oncogene transformation of NIH3T3 cells by protease inhibitors

The protease inhibitors antipain, leupeptin, alpha 1-antitrypsin, and epsilon-aminocaproic acid were found to inhibit transformation of NIH3T3 cells after transfection with an activated H-ras oncogene. Inhibition of focus formation by protease inhibitors was concentration dependent and maximal at 50% of control values. Transfection of a gene for neomycin resistance was not affected by protease inhibitors. Antipain was inactive if present only during the first 2 days of the gene transfer protocol or only during the final 10 days of the experiment. However, the full effect was observed when antipain was added at the subculture step on day 3 and during the subsequent cell proliferation. If cells were not subcultured, the yield of the foci per microgram of DNA was sharply reduced and addition of antipain did not further suppress the transformation rate. Subculture of NIH3T3 cells 3 days after transfection at lower cell densities resulted in higher transformation efficiency. The results suggest that transformation of NIH3T3 cells by a single mutated oncogene may involve multiple stages including cell proliferation and that part of this process is susceptible to inhibition by protease inhibitors.     

Partial down-regulation of protein kinase C in C3H 10T 1/2 mouse fibroblasts transfected with the human Ha-ras oncogene

Biochemical and immunological comparison of mouse C3H 10T 1/2 fibroblasts and C3H 10T 1/2 fibroblasts transfected with human activated Ha-ras oncogene indicated significantly lower levels of protein kinase C (PKC) activity and protein in the ras-transfected cells. This effect was observed in three clonal cell lines transfected with an activated ras oncogene. Cytosolic extracts of the ras-transfected cells contained calcium-activated, phospholipid-dependent protein kinase (PKC) activity at 61% of the level of activity present in C3H 10T 1/2 cells. A similarly decreased level of phorbol ester-binding activity was observed in these cells. Analysis of the subcellular distribution of PKC activity in cells failed to indicate significant differences between these cell lines. Immunoblots showed a lower abundance of the Mr 80,000 PKC in ras-transfected cell homogenates and extracts compared to C3H 10T 1/2 cells. Both C3H 10T 1/2 cells and cells transfected with ras expressed only one of the PKC isozymes as resolved by hydroxylapatite chromatography demonstrating that ras transfection of cells did not induce expression of alternative PKC isozymes. These observations indicate that PKC was partially down-regulated in ras-transfected cells, perhaps resulting from constitutively elevated levels of products of phosphatidylinositol-4,5-bisphosphate hydrolysis. Although C3H 10T 1/2 cells were previously shown to be distinct from NIH 3T3 cells in their sensitivity to transformation by the T24-ras oncogene, ras transformation appears to partially down-regulate PKC in C3H 10T 1/2 cells in a manner identical to that for ras-transformed NIH 3T3 cells. This indicates that down-regulation of PKC directly results from the expression of an activated ras oncogene independently of cellular sensitivity to transformation by expression of ras. The common action of ras transformation and phorbol esters to down-regulate PKC provides a possible mechanism for synergism during multistage carcinogenesis.     

Dependency of the efficiency of transformation by simian-virus-40 on the proliferative state of cultured fibroblasts at the time of virus inoculation

We previously demonstrated that the efficiency of cell transformation by simian virus 40 (SV40) is reduced when proliferating rat 3Y1 cells are inoculated with SV40 as compared with when density-arrested cells are inoculated. In this study, we characterized in more detail the cellular state at the time of virus inoculation that affects the susceptibility to SV40 transformation. When density-arrested 3Y1 cells were stimulated to progress one round of cell cycle by refeeding with medium containing high serum, they began to reduce the susceptibility to SV40 transformation before entering S phase. After re-entry into the non-proliferative state, prolonged maintenance of cells in the non-proliferative state was necessary for restoration of the susceptibility to SV40 transformation. Such dependency of the transformation efficiency on the cellular state at the time of SV40 inoculation paralleled with that of the expression of T antigen in nuclei, while virus adsorption and degradation of the DNA of the adsorbed virus was not dependent on the cellular state. We conclude that after inoculation of proliferating cells with SV40, an unidentified event between the virus adsorption and the accumulation of T antigen protein in nuclei is blocked and that this blockage causes the inhibition of the initiation of transformation.