Metastatic potential of cloned murine melanoma cells transfected with activated c-Ha-ras

We sought to determine whether the transfection of tumorigenic but not metastatic cells with the activated c-Ha-ras oncogene was invariably associated with acquisition of the metastatic phenotype. Three clonally derived lines of the K-1735 murine melanoma, characterized as nonmetastatic or poorly metastatic, were transfected with plasmids containing the 6.6-kilobase BamHI fragment of the mutant human c-Ha-ras gene and the neo gene, that confers resistance to neomycin (pSV2neoEJ). Cells transfected with pSV2neo, a plasmid containing the neo gene, served as controls for the procedure of Polybrene-mediated transfection. All cell lines were injected into syngeneic C3H/HeN and into athymic mice, and the results were compared with those produced by highly metastatic K-1735 M-2 cells. Although the pSV2neoEJ-transfected cells produced more rapidly growing s.c. tumors than the control cell lines did, the incidence of spontaneous metastasis was not increased. Following i.v. inoculation, the c-Ha-ras transfectants were retained in lung vasculature in greater proportions than pSV2neo counterpart transfectants were. The c-Ha-ras transfectants also produced significantly more lung tumor colonies, which grew faster than the few lung tumor colonies in mice given injections of control melanoma cells. We concluded that transfection of the activated c-Ha-ras oncogene into nonmetastatic K-1735 melanoma cells leads to accelerated tumor growth in vivo and can confer the ability to form lung colonies after i.v. injection but not the ability to metastasize from a primary s.c. tumor.     

Permanent conversion of mouse and human cells transformed by activated ras or raf genes to apparently normal cells by treatment with the antibiotic azatyrosine

Azatyrosine [L-beta-(5-hydroxy-2-pyridyl)-alanine], an antibiotic isolated from Streptomyces chibanensis, inhibited the growth of NIH 3T3 cells transformed by the activated human c-Ha-ras gene but did not significantly inhibit the growth of normal NIH 3T3 cells. Surprisingly, upon treatment with azatyrosine most of the transformed cells apparently became normal. These apparently normal cells, named revertant cells, grew in the presence of azatyrosine and stopped growing when they reached confluency, and their normal phenotype persisted during prolonged culture in the absence of azatyrosine. The revertant cells did not grow in soft agar and scarcely proliferated in nude mice. The human c-Ha-ras gene present in transformed NIH 3T3 cells was still present in the revertant cells and was expressed to the same extent as in the original transformed cells, producing the same amount of activated p21. Treatment with azatyrosine caused similar conversion of NIH 3T3 cells transformed by activated c-Ki-ras, N-ras, or c-raf to apparently normal cells, but NIH 3T3 cells transformed by hst or ret were not exclusively converted by azatyrosine. Human pancreatic adenocarcinoma cells, which are known to contain an amplified activated c-Ki-ras gene and an amplified c-myc gene, were also converted to flat and giant revertant cells by treatment with azatyrosine.     

Antipain-induced suppression of oncogene expression in H-ras-transformed NIH3T3 cells

Antipain (AP; 50 micrograms/ml) inhibits transformation of NIH3T3 cells after transfection with an activated H-ras oncogene. To determine whether AP effects on transformation are associated with alterations in oncogene expression, NIH3T3 cells were cotransfected with an activated H-ras oncogene and the selectable marker gene aph, and gene expression was quantified. Fifty percent of geneticin-resistant colonies which were exposed to AP failed to express the transformed phenotype as determined by their inability to grow in soft agar. Northern blot analysis of the transformed and nontransformed colonies revealed that suppression of H-ras transformation by AP was associated with a decrease in expression of the exogenously transfected H-ras gene by approximately 4-fold. Expression of the endogenous oncogene c-myc was decreased by approximately 2.5-fold, to levels seen in untransfected cells. AP-treated colonies that retained the transformed phenotype had levels of oncogene expression that were similar to untreated ras-transformed colonies. Southern blot analysis revealed no effects of AP on incorporation or copy number of the H-ras gene.     

Reversible suppression by nalidixic acid of anchorage-independent growth of mouse cells transformed by 3-methylcholanthrene or an activated c-Ha-ras gene

Effects of nalidixic acid and its derivatives were investigated on mouse cells transformed by methylcholanthrene or an activated c-Ha-ras oncogene. Our findings were as follows. Nalidixic acid preferentially suppressed growth in soft agar of transformed Balb/3T3 mouse cells induced by methylcholanthrene. The suppressive effect of nalidixic acid on growth in soft agar was reversible. Nalidixic acid reversibly reduced saturation density of these transformed cells. Oxolinic acid and pipemidic acid, which are derivatives of nalidixic acid, were less effective than nalidixic acid in suppressing growth in soft agar. Nalidixic acid suppressed growth in soft agar of NIH/3T3 mouse cells transformed by an activated c-Ha-ras, without affecting the amount of ras p21 proteins as detected by an immunoblotting analysis using a monoclonal antibody. These results show that nalidixic acid reversibly suppressed the expression of transformed phenotypes that were already being expressed.     

No acquisition of metastatic capacity of R1H rhabdomyosarcoma upon transfection with c-Ha-ras oncogene

The effect of the activated c-Ha-ras oncogene on invasiveness and formation of spontaneous metastases was studied using the rhabdomyosarcoma R1H of the rat. R1H tumor cells which are able to grow in vitro and produce tumors upon subcutaneous injection in syngeneic WAG/Rij rats were transfected with the c-Ha-ras (EJ) oncogene and the neomycin gene for selection. Two R1H cell lines harboring and expressing the human c-Ha-ras oncogene, one cell line containing the neomycin gene only, and the parent R1H cell line were compared. The expression of the transfected c-Ha-ras oncogene was assessed by Northern blot analysis and by flow cytometry using antibodies against ras p21. No difference in tumor growth rate and morphology was observed for the transfected and untransfected cell lines. Tumor volume doubling time was about 2 days in R1H-ras as well as in R1H parent tumors. Formation of spontaneous metastases was tested by excising the tumors when they had reached a volume of 2 cm3; after that the animals were observed up to 12 months. The excised tumors still contained and expressed the transfected ras oncogene as proved by Southern blot analysis and antibody staining using anti-ras p21. In contrast to most previous work on ras-transfected tumorigenic cells the R1H-ras tumors did not acquire invasive growth potential or increased metastatic capacity.     

Correlation of growth capacity of cells in hard agarose with successful transfection by the activated c-Ha-ras oncogene and in vivo proliferative capacity at metastatic sites

The purpose of this study was to determine whether the degree of anchorage-independent growth of rodent or human cells in increasing concentrations of agarose correlated with successful transfection of the cells with an activated c-Ha-ras oncogene and tumorigenicity in nude mice. NIH 3T3 cells, C3H 10T1/2 fibroblasts, four clones of the murine K-1735 melanoma with different metastatic capacities and the TE85 human osteogenic sarcoma line were transfected with plasmids containing the 6.6-kilobase BamHI fragment of the mutant human c-Ha-ras gene and the neo gene, which confers resistance to neomycin (pSV2-neoEJ). Cells transfected with pSV2-neo, a plasmid containing the neo gene, served as controls. Cells from parental or transfected lines (selected by Geneticin) were plated into medium containing 0.3%, 0.6% 0.9%, or 1.2% agarose. These cells were also injected subcutaneously and intravenously into nude mice. The production of tumor cell colonies in dense agarose (greater than or equal to 0.6%) correlated with successful transfection with pSV2-neoEJ and production of experimental metastases in the lung of nude mice. We conclude that the degree of anchorage-independent growth of cells predicts successful transfection with activated c-Ha-ras oncogene and tumorigenic behavior in vivo. Thus this technique may be useful for the detection of cells transfected with transforming oncogenes.     

Role of the Ha-ras (RasH) oncogene in mediating progression of the tumor cell phenotype (review)

Recent experimental evidence indicates that the c-Ha-ras (rasH) oncogene may be causally involved in the etiology and evolution of specific human neoplasms. In addition, cultured cells transformed by the rasH oncogene can induce both a tumorigenic and a metastatic phenotype when expressed in appropriate cultured cells. To begin to define the molecular and biochemical mechanism(s) by which the rasH oncogene induce their effects on expression of the transformed state we have employed a cloned rat embryo fibroblast (CREF) cell line. Transformation of CREF cells with wild-type 5 adenovirus (Wt) results in transformed cells which display anchorage-independence and an increased saturation density in monolayer culture, but are non-tumorigenic in both athymic nude mice and syngeneic Fischer rats. In contrast, when CREF cells are transformed with mutant type 5 adenoviruses, such as H5hrl, or the ElA transforming gene from hrl (0-4.5), tumors are induced in both nude mice and syngeneic rats. However, hrl (0-4.5)-transformed CREF cells are not metastatic following intravenous injection into the tail vein of syngeneic rats. Insertion of an activated T24 rasH oncogene or a wild-type v-rasH oncogene into CREF, wt-transformed CREF or hrl (0-4.5)-transformed CREF cells results in acquisition of a metastatic phenotype by these cells. A mutant v-rasH oncogene (mutant 116K), which is defective in GTP binding and the induction of transformation of NIH 3T3 cells, does not induce transformation in CREF cells, but it can progress wt-transformed CREF cells to a tumorigenic-non-metastatic state. Employing this model system which displays well-defined and stable stages in the tumor cell progression lineage, we have analyzed the potential role of changes in the phosphatidylinositol (PI) cycle and phospholipase A2 (PLA2) enzyme activity during progression to a tumorigenic and metastatic phenotype. An increase in PI cycle intermediates (primarily inositol triphosphate; IP3) were observed only in the wt-transformed and hrl (0-4.5)-transformed CREF cell lines transfected with the rasH oncogene. In the case of PLA2, all rasH-transformed CREF cell lines displayed increased activity. In contrast, CREF cells transformed only by Ad5 (Wt or hrl (0-4.5)) or the 116K v-rasH oncogene did not display increased PLA2 activity similar to that observed in rasH transfected cells. Since one important metabolite generated by PLA2 is arachidonic acid, which is converted into prostaglandins and leukotrienes by cyclooxygenase or lipooxygenase, respectively, the levels of prostaglandin E2 (PGE2) in the various cell lines were monitored.(ABSTRACT TRUNCATED AT 400 WORDS)     

Novel phenotype of C3H 10T1/2 fibroblasts cotransfected with the c-Ha-ras and adenovirus 5 E1A oncogenes

C3H 10T1/2 fibroblasts are converted to fully transformed phenotype following coexpression of an activated c-Ha-ras gene and either a constitutively expressed viral or cellular myc gene. In this report, we examined whether the early region 1A (E1A) of adenovirus 5, which synergizes with ras to convert primary embryonic cells to a transformed phenotype, can synergize with ras to transform the established mouse embryonic cell line, C3H 10T1/2. We demonstrate that coexpression of ras and E1A generated a transformed phenotype that could be scored by colony assays and by soft agarose assays but not by standard focus assays. The ras-E1A-transformed phenotype relies on sequences present in conserved regions 1 and 2 of the E1A proteins and, in part, on information encoded by the extreme carboxy terminus of E1A. The contrast between the transformed phenotypes generated following the transfection of C3H 10T1/2 cells with either ras and myc or ras and E1A suggests that myc and E1A cooperate with ras to transform C3H 10T1/2 cells by mechanisms that can be distinguished using this established cell line as a model system.     

Effects of triiodothyronine and tamoxifen on cell transformation induced by an activated c-Ha-ras oncogene

We have found that the thyroid hormone 3,5',3'-triiodo-L-thyronine stimulates the transformation of Rat 6 fibroblasts when these cells are transfected with an activated human c-Ha-ras oncogene (T24). 3,5',3'-Triiodo-L-thyronine did not further augment the stimulation of oncogene-induced transformation obtained with a phorbol ester tumor promoter (12-O-tetradecanoylphorbol-13-acetate) or a factor from fetal calf serum. On the other hand, tamoxifen, an antiestrogen that also inhibits protein kinase C, markedly inhibited Ha-ras-induced cell transformation in the presence of 12-O-tetradecanoylphorbol-13-acetate or fetal calf serum. Time course studies and Southern blot analyses of DNAs isolated from transformed foci provided evidence that 3,5',3'-triiodo-L-thyronine and tamoxifen do not exert their effects simply by enhancing or inhibiting integration of the transfected oncogene into cellular DNA. These findings indicate that hormonal factors can modulate the ability of an activated Ha-ras oncogene to transform cells. They may be relevant to the process of multistage carcinogenesis in vivo.     

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.     

Co-regulation of metastatic and transforming activity of normal and mutant ras genes

We have analyzed the metastatic properties of NIH-3T3 cells transformed by H-ras activated through over-expression and/or mutation. Our results reveal that elevated expression of H-ras proto-oncogene can induce the complete metastatic phenotype. Cells transformed by the proto-oncogene have a lower metastatic potential than those transformed by a mutated ras gene. ras oncogenes activated through alterations in codon 12 which encode p21 molecules with impaired GTPase activity, or in codon 59 which produce p21 molecules that release bound guanine nucleotide faster, or in codon 61 which produce p21 having impaired GTPase activity and altered nucleotide release properties, are all able to induce the metastatic phenotype. Leucine-61-activated oncogenes with an additional mutation in codons 116, 117 or 119, resulting in a reduced affinity for guanine nucleotides, are also capable of inducing metastatic behavior. These data indicate that ras genes which are capable of transforming are also capable of inducing the full metastatic phenotype in NIH-3T3 cells. This suggests that both phenotypes are induced through an increase in p21-GTP concentration in ras-transformed cells. This established model for ras-mediated transformation can also explain the qualitative and quantitative regulation of metastatic behavior by ras.     

Tumorigenicity in the nude mouse of cocultures derived from two nontumorigenic cell types, human pituitary adenomas and mouse C3H 10T1/2 fibroblasts

Human pituitary adenoma tissues were not tumorigenic in the hormonally manipulated nude mouse. Mouse fibroblast cells (C3H 10T1/2) also did not form tumors when inoculated alone into nude mice. When these two tissues were cocultured and coinoculated into nude mice however, the majority of inocula developed progressively enlarging tumors which could be established in tissue culture and passaged through the nude mouse. These tumors were sarcomatous histologically and thus did not resemble any human pituitary adenoma tissue injected. In order to detect any human cells in these tumors, tumor genomic DNA was subjected to Southern analysis using human repetitive Alu and HGH DNA sequence probes. Southern blot analysis of the nude mouse derived tumor genomic DNA revealed no sizeable human DNA in the mouse tumor cell genome indicating the absence of significant numbers of human cells in the tumors or the transfer of human DNA to the mouse cells. The tumors therefore arose from transformed C3H 10T1/2 cells after coculture with the human pituitary adenoma cells. These results implied that the tumorigenic transformation of susceptible C3H 10T1/2 cells in the cocultures occurred as a result of the secretion by the adenoma cells of transforming substances in the culture media or the induction of tumorigenicity through direct cell-cell contact between the two cell types.     

A cell line from Wilms' tumour with deletion in short arm of chromosome II

A cell line (T3/73) from a Wilms' tumour has been established from a 9 month-old boy with aniridia. The tumour was removed in 1973. On histological examination a diagnosis of Wilms' tumour was made which showed undifferentiated areas, marked tubule formation and abundant striped muscle fibres. The tumour cells, which are fusiform, grew rapidly in culture without the addition of growth factors, and have undergone over 100 passages. Approximately 95% and 5% were positive for desmin and cytokeratin, respectively. The cell doubling time was 28 hr. Cytogenetic studies revealed a karyotype of 46,XY,del(11) (p12::p14). Although the cells stained very intensely with a monoclonal antibody that detects oncogene ras p 21 antigen, Southern blot analysis using c-Ha-ras as a probe failed to reveal an obvious deletion or amplification of either Ha-ras allele.     

Spontaneous Ha-ras gene activation in cultured primary murine keratinocytes: consequences of Ha-ras gene activation in malignant conversion and malignant progression

The activation of the c-Ha-ras gene and its contribution to the tumorigenic phenotype were examined in cultured mouse keratinocytes and squamous tumors using transfection into NIH 3T3 cells and nucleic acid hybridization. When normal keratinocytes were cultured in medium with 0.05 mM Ca2+ (low Ca2+ medium), many cells died within 2-3 wk, while others formed rapidly growing foci that could be subcultured. These rapidly growing cells produced benign tumors when grafted to nude mice and possessed a heterozygous mutation in the c-Ha-ras gene with an A----T transversion in codon 61. Fibroblast-conditioned low Ca2+ medium prevented cell death, focus formation, c-Ha-ras gene mutation, and tumorigenicity. Thus, suboptimal culture conditions favored a spontaneous mutation in codon 61 of the c-Ha-ras gene of keratinocytes. When a v-Ha-ras gene was introduced into normal keratinocytes by a replication-defective retrovirus, the recipient cells produced papillomas in vivo, and after 2 mo, 60% of the tumors converted to squamos cell carcinomas. None of the 22 converted tumors had an endogenous c-Ha-ras gene mutation at codon 61. However, the A----T transversion mutation developed when these carcinoma cells were cultured in low Ca2+ medium but not in fibroblast-conditioned medium. Cells with both an exogenous v-Ha-ras and an activated c-Ha61-ras gene produced undifferentiated, rapidly lethal carcinomas, while cells with only v-Ha-ras maintained the squamous carcinoma phenotype. Undifferentiated carcinomas also developed when the v-Ha-ras gene was introduced into papilloma cells with a chemically induced endogenous c-Ha61-ras gene mutation. These results suggest that mutation in the c-Ha-ras gene can contribute to initiation, malignant conversion, and malignant progression in skin carcinogenesis, and gene dosage may determine the phenotype expressed.