Frequent induction of mammary carcinomas following neu oncogene transfer into in situ mammary epithelial cells of susceptible and resistant rat strains

Varying results have been reported on the role of neu oncogene in mammary carcinogenesis. In order to further address this issue, the activated neu oncogene was introduced into mammary epithelial cells in situ of both mammary carcinoma-susceptible Wistar Furth and resistant Copenhagen rats by infusing replication-defective recombinant retroviruses carrying the neu oncogene into the mammary gland lumen. At the highest virus titer tested, very high numbers of mammary carcinomas developed within 2 weeks in all exposed glands in both rat strains. When the virus titer was reduced, however, individual tumors occurred with varying latencies. In addition, not all of the neu-infected mammary cells progressed to form mammary carcinomas. These results suggest that while neu is a potent mammary transforming gene, either other events in addition to neu expression may be required for full malignant transformation or not all mammary ductal epithelial cells are able to be neoplastically transformed.     

Neoplastic transformation of human epithelial cells in vitro

Efforts to investigate the progression of events that lead human cells of epithelial origin to become neoplastic in response to carcinogenic agents have been aided by the development of tissue culture systems for propagation of epithelial cells. We have recently developed an in vitro multistep model suitable for the study of human epithelial cell carcinogenesis. Primary human epidermal keratinocytes acquired indefinite lifespan in culture but did not undergo malignant conversion in response to infection with Adl2-SV40 virus. Subsequent addition of Ki-MSV, which contains a K-ras oncogene, to these cells induced morphological alterations and the acquisition of neoplastic properties. Nontumorigenic human epidermal keratinocytes immortalized by Adl2-SV40 virus (RHEK-1) were also transformed by treatment with chemical carcinogens (MNNG or 4NQO) and by X-ray irradiation. Such transformants showed morphological alterations and induced carcinomas when transplanted into nude mice. This in vitro system may be useful in assessing environmental carcinogens for human epithelial cells and in detecting new human oncogenes since ras oncogenes were not activated in these chemical--or X-ray--transformed RHEK-1 lines. Subsequently, it was found that this line could be transformed neoplastically by a variety of retroviruses containing H-ras, bas, fes, fms, erbB and src oncogenes. In addition, our recent results indicate that nontumorigenic RHEK-1 cells can be transformed following transfection with an activated human oncogene. Thus, this in vitro system may be useful in studying the interaction of a variety of carcinogenic agents and human epithelial cells. These findings demonstrate the malignant transformation of human primary epithelial cells in culture by the combined action of tumor viruses and chemical carcinogens or X-ray irradiation and support a multistep process for neoplastic conversion. Further, evidence for the multistep nature of neoplastic transformation of human epithelial cells in vitro using other model systems is presented.     

Conditional immortalization and/or transformation of rat cells carrying v-abl or EJras oncogene in the presence or absence of glucocorticoid hormone

Early-passaged rat chondroblasts (RX cells) and embryonal fibroblasts (RE cells) are hardly transformed by transfection of activated human H-ras (EJras) or by Abelson murine leukemia virus v-abl oncogene. However, these cells were transformed by v-abl or EJras gene when dexamethasone (DX) was added in the culture medium as well as when co-transfected with retrovirus LTR-linked mouse c-myc gene. RX cell lines carrying v-abl (RXabl), RE cell lines carrying v-abl (REabl) and RX cell lines carrying EJras (RXEJ) were established from transformed colonies in the DX-added soft agar. In the absence and in the presence of DX, RXabl cells showed mortal and immortalized, REabl cells showed mortal and transformed, and RXEJ cells showed immortalized and transformed phenotypes, respectively. Especially, immortalization and transformation of REabl1 and REabl3 lines were switched on and off by addition and depletion of DX. v-abl or EJras mRNA levels in tested REabl, RXabl and RXEJ lines cultured without DX was not decreased compared to those cultured with the hormone. The above suggests that, like myc gene, glucocorticoid collaborates with v-abl or activated ras oncogene to transform unestablished rat cells and that the transformation phenotypes were determined not only by the introduced oncogene but by the cellular condition including their tissue origin. Transformation of senescent REabl cells in the absence of DX was tested by transfecting different oncogenes. Among nuclear oncogenes tested, only adenovirus 12 E1A gene could induce transformation of G0-arrested REabl cells in a cooperative fashion with the integrated v-abl gene.     

Transformation of human mammary epithelial cells by oncogenic retroviruses

We have introduced viral oncogenes into human mammary epithelial cells through the use of murine retroviruses. A continuous cell line (184A1N4) derived from benzo(a)pyrene treatment of normal breast epithelial cells was used as a recipient for the ras, mos, and T-antigen oncogenes. Each of these oncogenes enabled the 184A1N4 cells to grow in a selective medium, thus demonstrating the potential utility of these cells for oncogene detection and isolation. 184A1N4 cells transformed by T-antigen were nontumorigenic in athymic mice, but v-ras transformants were weakly tumorigenic. Transformants bearing both the T-antigen and ras oncogenes were strongly tumorigenic, however. The karyotype of these double transformants shows a high degree of stability. These results demonstrate the stepwise acquisition of the fully malignant phenotype by normal human epithelial cells in vitro.     

Carcinoma induction following direct in situ transfer of v-Ha-ras into rat mammary epithelial cells using replication-defective retrovirus vectors

Chemically induced mammary carcinomas often contain the activated Ha-ras oncogene. The role of this oncogene in the multistage process of carcinogenesis remains undefined. In order to model the role of ras in mammary carcinogenesis, gene transfer into adult rat mammary epithelial cells was accomplished by infusing helper-free, replication-defective retrovirus vectors into the central duct of each gland. In the initial experiments, the beta-galactosidase reporter gene was used to optimize the efficiency of this in situ gene transfer method. Stable infection of greater than 0.1% of mammary cells could be achieved following exposure to the beta-galactosidase gene-expressing vector. v-Ha-ras was then introduced into in situ adult rat mammary epithelial cells using this method. Cellular infection frequencies of less than 1% resulted in the frequent and rapid appearance of mammary carcinomas without any further treatment. Tumors arising following v-Ha-ras oncogene transfer resembled those induced by chemical carcinogens in both the kinetics of their development and histopathological spectrum. These observations support the hypothesis that ras activation can act as an initiation event in chemically induced mammary carcinogenesis. However, only a small percentage of v-Ha-ras infected cells, even with hormonal promotion, were neoplastically transformed, suggesting that ras-driven transformation is not a one-step event.     

Partial transformation of human thyroid epithelial cells by mutant Ha-ras oncogene.

We have previously shown that activation of ras oncogenes by mutation is a frequent early event in human thyroid neoplasia. Using amphotropic retroviral vectors to achieve gene transfer, we demonstrate here that human primary thyroid epithelial cells can be partially transformed by an activated cellular or viral Ha-ras oncogene, in the absence of a cooperating oncogene. The transformation event induced by ras involves temporary rescue from senescence for up to 20 rounds of cell division together with morphological alteration, growth factor independence and anchorage independence. It has therefore been possible to reconstruct in vitro a key early event in the genesis of human epithelial neoplasia.     

The ras oncogene-mediated sensitization of human cells to topoisomerase II inhibitor-induced apoptosis

BACKGROUND: Among the inhibitors of the enzyme topoisomerase II (an important target for chemotherapeutic drugs) tested in the National Cancer Institute's In Vitro Antineoplastic Drug Screen, NSC 284682 (3'-hydroxydaunorubicin) and NSC 659687 [9-hydroxy-5,6-dimethyl-1-(N-[2(dimethylamino)ethyl]carbamoyl)-6H-pyrido -(4,3-b)carbazole] were the only compounds that were more cytotoxic to tumor cells harboring an activated ras oncogene than to tumor cells bearing wild-type ras alleles. Expression of the multidrug resistance proteins P-glycoprotein and MRP (multidrug resistance-associated protein) facilitates tumor cell resistance to topoisomerase II inhibitors. We investigated whether tumor cells with activated ras oncogenes showed enhanced sensitivity to other topoisomerase II inhibitors in the absence of the multidrug-resistant phenotype. METHODS: We studied 20 topoisomerase II inhibitors and individual cell lines with or without activated ras oncogenes and with varying degrees of multidrug resistance. RESULTS: In the absence of multidrug resistance, human tumor cell lines with activated ras oncogenes were uniformly more sensitive to most topoisomerase II inhibitors than were cell lines containing wild-type ras alleles. The compounds NSC 284682 and NSC 659687 were especially effective irrespective of the multidrug resistant phenotype. The ras oncogene-mediated sensitization to topoisomerase II inhibitors was far more prominent with the non-DNA-intercalating epipodophyllotoxins than with the DNA-intercalating inhibitors. This difference in sensitization appears to be related to a difference in apoptotic sensitivity, since the level of DNA damage generated by etoposide (an epipodophyllotoxin derivative) in immortalized human kidney epithelial cells expressing an activated ras oncogene was similar to that in the parental cells, but apoptosis was enhanced only in the former cells. CONCLUSIONS: Activated ras oncogenes appear to enhance the sensitivity of human tumor cells to topoisomerase II inhibitors by potentiating an apoptotic response. Epipodophyllotoxin-derived topoisomerase II inhibitors should be more effective than the DNA-intercalating inhibitors against tumor cells with activated ras oncogenes.     

Activation of the c-Ha-ras-1 proto-oncogene by methylation in vitro with alpha-acetoxy-N-nitrosodimethylamine

alpha-Acetoxy-N-nitrosodimethylamine, an activated derivative of the carcinogen N-nitrosodimethylamine, methylated in vitro a plasmid containing the human c-Ha-ras-1 proto-oncogene, resulting in the generation of a transforming oncogene, assayed by transfection into NIH 3T3 cells. The resulting transformed cells were tumorigenic and metastatic in immune-deprived mice. Further transfection using tumor DNA led to the formation of three secondary NIH 3T3 transformants. DNA from these secondary transformants contained human ras gene sequences. Two of the three secondary transformants contained G----A mutations at guanine 35 in codon 12, and the third secondary transformant retained the wild-type sequence at codons 12, and 61. For the latter, the activating mutation was not determined. These results demonstrate that a simple methylating agent can activate a normal human ras proto-oncogene to a transforming oncogene.     

Detection of transforming oncogenes in rat colon tumors induced by direct perfusion with N-methyl-N-nitrosourea.

We assayed rat colon tumors induced by N-methyl-N-nitrosourea (MNU) for transforming oncogenes by the NIH 3T3 transfection and nude mouse tumorigenicity assays. Transfection of DNA from 3 of 3 adenomas and 3 of 5 carcinomas induced transformed foci on NIH 3T3 cells. DNA from 2 of 3 primary foci also possessed focus-forming activity, and rat-specific sequences were observed in secondary focus DNAs. Furthermore, NIH 3T3 cells transfected with DNA from a carcinoma and from a primary focus derived from it, both positive in the focus-forming assay, induced tumors in nude mice. We found no evidence for rat H-ras, K-ras, or N-ras sequences in the DNA of any of 16 primary foci derived from 6 rat tumors; thus, in contrast to other animal tumor models induced by MNU, activation of the ras genes does not appear to predominantly occur in MNU-induced rat colon tumors. We also did not observe, in any of these foci, sequences corresponding to the rat neu, raf, fms, met, or hst genes, thus indicating that none of these is the transforming oncogene in our model. These results suggest that an as yet unidentified transforming oncogene may be activated in rat colon tumors induced by MNU.     

Ras oncogene-induced sensitization to 1-beta-D-arabinofuranosylcytosine

Human tumor cells containing ras oncogenes display enhanced sensitivity to 1-beta-D-arabinofuranosylcytosine (Ara-C) and other deoxycytidine analogues (H-M. Koo, et al., Cancer Res., 56: 5211-5216, 1996). Human tumor cell lines with or without a ras oncogene as well as a pair of isogenic cell lines with one containing an activated ras oncogene were used to study the basis for differential sensitivity. We found that human tumor cells containing ras oncogenes upon entry into the S phase of the cell cycle underwent apoptosis in response to Ara-C treatment. By contrast, human tumor cells harboring wild-type ras alleles were only delayed in the S phase when exposed to Ara-C. Thus, the ras oncogene specifically renders human cells more sensitive to Ara-C by preventing S-phase arrest. This may occur by the ras oncogene compromising an S-phase checkpoint.     

p53 mutations, ras mutations, and p53-heat shock 70 protein complexes in human lung carcinoma cell lines.

The p53 tumor suppressor gene is frequently mutated and the K-ras oncogene is occasionally mutated in primary specimens of human lung carcinomas. These mutated genes also cooperate in the immortalization and neoplastic transformation of rodent cells. To determine whether these mutations are necessary for maintenance of the immortalized and/or neoplastically transformed states of human bronchial epithelial cells, the p53 gene and regions of the ras (K-, H-, and N-) genes were sequenced in nine human lung carcinoma cell lines. Detection of p53 mutations by polymerase chain amplification and direct DNA sequencing was corroborated by p53 immunocytochemistry and coimmunoprecipitation of p53 with heat shock protein 70. p53 and ras genes were frequently, but not always, mutated in the carcinoma cell lines. These data are consistent with the hypothesis that multiple genetic changes involving both protooncogenes and tumor suppressor genes occur during lung carcinogenesis.     

Transformation-specific Decrease of Phosphorylation of 80K Protein, a Substrate of Protein Kinase C, in NIH3T3 Cells

Phosphorylation in normal and transformed NIH3T3 cells of the 80K protein, a specific substrate for protein kinase C, was compared by means of two-dimensional gel analysis. We obtained evidence that NIH3T3 cells transformed by the c- raf or H- ras oncogene maintained a decreased level of phosphorylation of the 80K protein, with or without phorbol ester (TPA)-stimulation, at all concentrations of serum tested while normal NIH3T3 cells maintained an elevated level of phosphorylation of the 80K protein. Furthermore, NIH3T3 cells transformed by N- ras , K- ras, src, mos or polyoma middle T antigen exhibited a decreased level of phosphorylation of the 80K protein. These events were confirmed by an analysis of a hormone-inducible H- ras transformant. Thus, phosphorylation of the 80K protein is inversely correlated with cellular transformation.     

Induction and progression of the transformed phenotype in cloned rat embryo fibroblast cells: studies employing type 5 adenovirus and wild-type and mutant Ha-ras oncogenes.

Transformation of cloned rat embryo fibroblast (CREF) cells with the wild-type 5 adenovirus (wtAd5) transforming genes E1A and E1B (which extend from 0 to 11.2 map units) results in morphologically transformed cells that exhibit an increased saturation density in monolayer culture and display an anchorage-independent phenotype. WtAd5-transformed CREF (wtAd5 CREF) cells do not, however, induce tumors when injected subcutaneously into athymic nude mice or syngeneic Fischer rats. We have analyzed the effect of the ras oncogene and site-specific mutants in the ras oncogene that result in p21 proteins with altered biochemical properties on the oncogenic and metastatic properties of singly (ras) and doubly (ras + wtAd5) transformed CREF cells. Transformants expressing the wild-type ras p21 protein and ras mutants producing p21 proteins that retained GTP-binding properties grew in agar, induced tumors in nude mice and syngeneic rats, and metastasized to the lungs of rats when injected into their tail veins. In contrast, cells transformed with the ras mutant 116K (which contains a mutation at residue 116 that produces a Lys instead of an Asn and does not bind GTP or induce CREF cells to grow in agar) did not become morphologically transformed and were not oncogenic when injected subcutaneously into either nude mice or Fischer rats; further, such cells were not metastatic when injected into the tail veins of Fischer rats. When the wild-type ras or the ras mutants, including 116K, were expressed in nontumorigenic E1A-plus-E1B-expressing wtAd5 CREF cells, transformed cells induced tumors in both types of animals. The CREF cells doubly transformed with 116K + wtAd5, unlike transformants containing the wild-type ras and the other ras mutants that still retained GTP binding, were still unable to induce lung metastases. In addition, 116K + wtAd5-transformed CREF cells also did not display any alterations in morphology distinguishable from wtAd5 CREF cells and were not able to grow in agar with increased efficiency. These results indicate that the loss of GTP-binding ability by this mutant p21 ras protein eliminated the ability of these proteins to induce an oncogenic phenotype in an immortal but normal CREF cell line. However, the mutant ras could cooperate with wtAd5 transforming genes in transformed CREF cells to make these cells progress to an oncogenic (but not metastatic) phenotype.     

N-methyl-N-nitrosourea-induced transformation of rat urothelial cells in vitro is not mediated by activation of ras oncogenes

Adult rat urothelial cells were transformed in vitro following treatment with a single dose of N-methyl-N-nitrosourea (MNU) or MNU treatment followed by promotion with sodium saccharin. This in vitro transformation process involves multiple steps: slow-growing 'pre-neoplastic' epithelial foci are induced 70-100 days after MNU treatment and from such foci rapidly proliferating immortal cell lines were established, some of which became tumorigenic after a further latent period. A series of epithelial cell lines and a single fibroblast cell line established in this way were analysed for the presence of transforming genes by DNA transfection into NIH3T3 cells. None of the epithelial cell lines induced foci in a focus formation assay. The single non-epithelial line induced foci and was found to contain an activated c-Ki-ras gene with a G----A transition in codon 12. To assay for the possible presence of transforming genes which were not active in a focus formation assay, two of the epithelial lines were analysed further by co-transfection with a dominant selectable marker, followed by selection and inoculation into nude mice. No tumours were induced within the latent period for tumour production by control cells transfected with NIH3T3 cell DNA (40-60 days). These results suggest that there is cell type specificity for oncogene activation during in vitro rat bladder transformation initiated by a single carcinogen and that ras gene activation is not a necessary step in urothelial transformation in vitro.     

Oncogene-mediated multistep transformation of C3H10T1/2 cells

We have examined the response of the mouse embryonic cell line C3H10T1/2 to transfection with the activated human c-H-ras oncogene and the gag-myc oncogene from avian myelocytomatosis virus 29. C3H10T1/2 cells are not morphologically transformed following transfection with the gag-myc oncogene. A low level of focus formation is observed following transfection of the c-H-ras oncogene. When C3H10T1/2 cells are cotransfected with the ras and myc oncogenes, focus formation is increased by an average of 13 fold. In addition, C3H10T1/2 ras/myc foci have a distinct, transformed morphology which correlates with an increased potential for anchorage-independent growth. Although morphological transformation in this system is largely a function of ras oncogene expression, our studies demonstrate that it is potentiated by the presence of a functional gag-myc protein. Oncogene-mediated multistep transformation, which was first described in primary embryo cultures, is not a general property of established cell lines. The C3H10T1/2 cell line is an exception and provides a model system in which partially transformed phenotypes, in a progression toward malignant transformation, can be isolated and studied.     

Separation of immortalization and T24-ras oncogene cooperative functions of adenovirus E1a

An adenovirus 2 E1a gene coding for a protein of 243 (243R) amino acids can efficiently immortalize primary rat kidney (BRK) cells and cooperate with the activated cellular ras oncogene (T24 ras). A mutant (47-0) of the 243R gene that maps between amino acid residues 47-50 within a region that is highly conserved among the various adenovirus serotypes was found to be severely defective in immortalization. Despite the defect in immortalization, mutant 47-0 had the ability to cooperate with T24 ras in oncogenic transformation. These results suggest that the immortalization and the oncogene cooperation functions of the 243R are separable. Our results further suggest that the requirement for a separate immortalization function can be circumvented by oncogenic transformation and that the immortalization of cells transformed by E1a and T24 ras may be a secondary consequence of transformation by these two oncogenes.     

Changes in rasT24 expression do not induce changes in c-jun, jun-B, or jun-D RNA levels in rat liver epithelial cells

We used a series of rat liver epithelial (RLE) cell lines that carry a zinc-regulatable metallothionein/rasT24 fusion gene (MTrasT24) to investigate the relation of ras oncogene expression to steady-state RNA levels of the jun family of genes. In these cells, steady-state RNA levels of c-jun, jun-B, and jun-D were unrelated to rasT24 RNA levels or the phenotypic changes induced by the ras oncogene. Steady-state levels of the three jun mRNAs varied among different rasT24 transformed clones, and, although some clones exhibited concomitant induction of rasT24 and jun mRNAs, other clones exhibited no such correlation. We conclude that the effects of rasT24 in transformed RLE cells do not appear to be mediated by c-jun, jun-B, or jun-D and that studies examining only a single transformed clone may give misleading results with respect to the role of various oncogenes in the transformation process.