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.     

Oncogenes conferring metastatic potential induce increased branching of Asn-linked oligosaccharides in rat2 fibroblasts

Increased -GlcNA beta-6 Man alpha 1-6 Man beta 1- branching of Asn-linked oligosaccharides has been observed in a number of rodent and human tumor cell lines and the structures have been correlated with enhanced metastatic potential of murine tumor cells. Here we have compared the malignant potential and levels of beta 1-6-branched oligosaccharides in rat 2 fibroblast transfected with the cytoplasmic tyrosine kinase v-fps/fes, the activated GTPase T24 H-ras, and the nuclear oncogene c-myc. Rat2 cells transfected with activated c-myc were non-tumorigenic in nude mice and did not show elevated levels of beta 1-6 branched oligosaccarides, whereas transfectants carrying H-ras or v-fps were tumorigenic and generally exhibited metastatic potential which was associated with increased beta 1-6 branching. Enhanced expression of beta 1-6 branched oligosaccharides did not correlate with increased ratios of UDP-HexNAc to UDP-Hex, but was accompanied by elevated GlcNAc-transferase V activity, increased sensitivity of the cells to the toxic effects of leukoagglutinin, and an altered intracellular distribution of beta 1-6-branched oligosaccharides as visualized by fluorescent lectin staining. These results provide information on the quantitative and qualitative relationships between oncogene expression and cellular glycosylation and suggest that the ability of an oncogene to confer metastatic potential may be related to its ability to induce increased branching of Asn-linked oligosaccharides.     

Natural killer cell regulation of implantation and early lung growth of H-ras-transformed 10T1/2 fibroblasts in mice

We examined the relative role of the natural killer (NK) cell and H-ras gene in controlling metastasis formation using a novel assay for quantitating viable tumor cells entering and surviving in the lung for up to 13 days following i.v. tumor inoculation. This assay utilized the resistance to G418 sulfate conferred by transfection of the neoR gene into 10T1/2 fibroblasts along with activated H-ras. We had previously shown that the metastatic efficiency of T-24-H-ras-transformed 10T1/2 fibroblasts correlated with H-ras expression at the RNA level. In this paper we show that the NK cell could recognize H-ras-transformed fibroblasts in vivo and control experimental metastasis formation using NK-suppressed and -activated syngeneic C3H recipients. Evaluation of NK sensitivity in vitro of individual lines did not predict metastatic ability. However, NK susceptibility in vitro did inversely correlate with the ability of tumor cells to arrest and survive in the lung for the first 48 h after i.v. inoculation. Although the level of H-ras RNA correlated with the ultimate metastatic potential, it did not correlate with the initial rate of tumor cell pulmonary retention or clearing. Over the next 10 to 12 days, however, we detected a preferential survival and outgrowth of high H-ras-expressing variants, which correlated well with the ultimate metastatic ability but not NK susceptibility. These observations argue that the NK cell has its major effect early in the course of the disease, while subsequent tumor growth occurs preferentially in high H-ras-expressing cell lines.     

Overexpression of ha-ras oncogene transforms rodent fibroblasts with low-frequency but not human-diploid fibroblasts

Activated Ha-ras oncogenes were introduced into early passage normal human adult dermal fibroblasts, 149BR and established mouse Swiss 3T3 fibroblasts by retroviral-mediated gene transfer or by DNA transfection, respectively. The presence and expression of Ha-ras oncogenes was followed by Southern and Northern blotting and immunoprecipitation. Overexpression of the human mutant c-Ha-ras1 T24 oncogene in mouse cells induced morphological transformation, focus formation and growth in soft agar with low frequency. Tumourigenicity studies showed that the malignant transformation of these cells by p21Ha-ras T24 oncoprotein was concentration-dependent and it required additional events suggesting that in vitro establishment is not a sufficient prerequisite for tumourigenic conversion by activated Ha-ras oncogenes. In contrast, constitutive expression of the viral Ha-ras oncogene in human diploid fibroblasts failed to immortalise or transform them. All ras-expressing human cells remained flat, anchorage-dependent and non-tumourigenic suggesting that these cells are resistant to transformation by activated oncogenes. The role of Ha-ras oncogenes in the transformation of mammalian cells in discussed.     

Expression of the c-Ha-ras oncogene in mouse NIH 3T3 cells induces resistance to cisplatin.

The effect of expression of the c-Ha-ras oncogene on cisplatin (DDP) sensitivity was examined in murine NIH 3T3 cells transfected with the dexamethasone (DEX)-inducible mouse mammary tumor virus promoter linked to an activated c-Ha-ras gene [LTR H-ras(A) cells]. Treatment of these cells with 5 microM DEX for 24 h induced c-Ha-ras expression and produced an 8.2 +/- 1.3-fold (SD) increase in DDP resistance as quantitated by clonogenic assay. Induction of the c-Ha-ras oncogene reduced DDP accumulation by 40% and intrastrand adduct formation by 17%. In nontransfected wild-type NIH 3T3 cells, DEX did not induce DDP resistance nor did it decrease DDP accumulation. Induction of c-Ha-ras expression did not alter cellular glutathione content or the activity of glutathione-S-transferase in the LTR H-ras(A) cells. DEX increased cellular metallothionein content by 1.6-fold in NIH 3T3 cells and 3.3-fold in LTR H-ras(A) cells. We conclude that DEX-induced overexpression of a mutant c-Ha-ras gene confers DDP resistance and that this resistance is associated with an impairment of cellular drug accumulation and an increase in metallothionein content.     

Functional interaction of p53 with HPV18 E6, c-myc and H-ras in 3T3 cells.

Wild-type (wt) p53 has been suggested to be the product of a tumor-suppressor gene. Recently, it has been shown that the E6 oncoproteins of human papillomavirus (HPV) types 16 and 18, like the SV40 large T antigen, are physically associated with wt p53. We have investigated the functional interaction of wt p53 with the viral oncogene products of HPV16 and 18 and with cellular oncogenes by transfection of NIH3T3 cells with p53 wt alone or with several oncogene(s). We found that over-expression of HPV18 E6, c-myc or activated H-ras, like SV40 large T, can partially overcome the growth-inhibitory effect of wt p53 in NIH3T3 cells, while HPV16 E6 and E7, HPV18 E7, k-fgf, c-fos and mutant (mt) p53 do not. Further studies indicate that HPV18 E6 and c-myc can overcome the antiproliferative effect, but not the antitransforming effect, of wt p53, while activated H-ras can overcome both the antiproliferative and antitransforming effects of wt p53. These data show evidence of a functional interaction between HPV18 E6 and wt p53, and suggest that the cooperation of HPV E6 and cellular oncogenes c-myc and H-ras, which are activated in several cases of human cervical cancers, may be necessary to overcome completely the anti-oncogenic function of p53 in the development of these tumors.     

The role of the H-ras oncogene in radiation resistance and metastasis

The sensitivity of tumor cells to the killing effects of ionizing radiation is thought to be one of the major determinants of curability of tumors in patients treated with radiation therapy. This paper reviews the evidence from our laboratory and other groups which supports a role for oncogenes in the induction of radioresistance in cultured mammalian cells. Primary rat embryo cells (REC) were chosen as a model system in which the effects on radiation resistance of the H-ras oncogene could be studied on a uniform genetic background. These cells offered several useful advantages. The cells prior to transformation are diploid and because they have been in culture only for a few passages prior to transformation with the oncogene it is unlikely that any preexisting mutation affecting radiation response could be present. Additionally, the use of REC permitted the study of the effects of synergism between oncogenes on the induction of the radioresistant phenotype. The results show that the activated H-ras oncogene induces radiation resistance in primary rat cells after transformation, but that the effect of the oncogene itself is small. However, the myc oncogene, which has no effect on radiation resistance by itself, appears to have a synergistic effect on the induction of radiation resistance by H-ras. Radiation resistance induced by H-ras plus myc is characterized by an increase in the slope of the curve at high doses but there is also a large effect within the shoulder region of the radiation survival curve. The AdenoE1A oncogene which will also act synergistically with ras in transformation assays plays a less clear-cut role in assays of radiation resistance. The H-ras oncogene is also known not only to transform cells but also to induce metastatic behavior in the tumors which form after these transformed cells are injected into syngeneic animals or nude mice. We have also shown in our primary rat embryo cell system that the induction of metastatic behavior in transformed cells, like the induction of radioresistance depends on a complex interaction between oncogenes and the cellular background. This evidence will be reviewed to demonstrate some of the analogies between radiation resistance and metastasis as examples of the complex alterations in cellular phenotype which occur after oncogene transfection.(ABSTRACT TRUNCATED AT 400 WORDS)     

Oncogene amplification in squamous cell carcinoma of the oral cavity

We have determined the prevalence of amplification of c-myc, N-myc, L-myc, H-ras, Ki-ras, and N-ras oncogenes in 23 cases of squamous cell carcinoma of the oral cavity, using Southern hybridization analysis of DNA extracted from the primary tumor tissues. Nick-translated oncogene probes and oncogene inserts labeled to high specific activities were used. We observed a 5- to 10-fold amplification of one or more of c-myc, N-myc, Ki-ras and N-ras oncogenes in 56% of the tumor tissue samples, with these oncogenes not being amplified in the peripheral blood cells of the same patients. L-myc and H-ras were not amplified in any of our samples. The oncogene amplifications seemed to be associated with advanced stages of squamous cell carcinomas, with the ras and myc family oncogenes being amplified in stages 3 and 4. Hybridization with N-myc detected an additional 2.3 kb EcoRI fragment, along with the normal 2.1 kb fragment. Our data also demonstrated amplification of multiple oncogenes in the same tumor tissue sample. About 60% of the samples with amplified oncogenes showed simultaneous amplification of 2 or more oncogenes. The results showing different oncogene amplifications in similar tumors, as well as multiple oncogene amplifications in the same tumor, suggest that these oncogenes may be alternatively or simultaneously activated in oral carcinogenesis.     

Morphological transformation, focus formation, and anchorage independence induced in diploid human fibroblasts by expression of a transfected H-ras oncogene

In an attempt to determine how normal human fibroblasts respond to high expression of the T24 H-ras oncogene, we tranfected such cells with the plasmid vector pHO6T1 (D. A. Spandidos and N. M. Wilkie, Nature (Lond.), 310:469-475, 1984), containing the T24 H-ras oncogene with 5' and 3' enhancer sequences, and the aminoglycoside phosphotransferase gene which confers resistance to the drug, G418. Approximately 1.5% of the G418-resistant colonies obtained after transfection and selection consisted of cells exhibiting obvious morphological transformation; i.e., they were highly refractile and more rounded than normal fibroblasts. DNA hybridization analysis showed that the morphologically transformed cells contained the transfected T24 H-ras oncogene, and radioimmunoprecipitation analysis showed that they were expressing the T24 H-ras protein product, M, 21,000 protein. Morphologically transformed cells formed colonies in soft agar at a frequency at least 60 times higher than that of cells that had been transfected with the control plasmid containing the normal cellular H-ras gene. Cells transfected with plasmid pHO6T1 could also be identified by their ability to form distinct foci when grown to confluence in nonselective medium following transfection. This study demonstrates that normal diploid human fibroblasts in culture can be transformed by transfection with a H-ras oncogene, and that such transformation correlates with expression of the mutant Mr 21,000 protein.     

Resistance of murine LTA cells to oncogene--mediated progression from tumorigenic to metastatic phenotype

We have previously shown that expression of the H-ras oncogene alone does not induce progression of a tumorigenic but non-metastatic murine fibroblast cell line (LTA) to a metastatic phenotype. Because myc genes, alone or with ras, have been implicated at different stages of progression in other systems, we examined the ability of v-myc, alone and in combination with H-ras, to induce malignant conversion of LTA. We found no increase in either "spontaneous" (assessed after s.c. injection into nude mice) or "experimental" (assessed after i.v. injection into chick embryos) metastatic ability in spite of high levels of v-myc RNA in LTA cells transfected with v-myc alone. Serial in vivo passaging did not consistently select for either myc expression or metastatic ability. Myc transfected cells expressing high levels of myc RNA were subsequently transfected with H-ras. LTA cells expressing both oncogenes at high levels remained non-metastatic. LTA cells thus are resistant to the effects of myc and ras oncogenes (alone and in combination) on a specific stage of tumor progression, that of malignant conversion, and may offer a good model for studying mechanisms of resistance to these oncogenes.     

Expression of heparanase, Mdm2, and erbB2 in ovarian cancer

Ovarian cancer is the most lethal of gynecological malignancies. Yet early diagnosis and prognosis are far from being satisfactory. Degradation of heparan sulfate proteoglycans by heparanase appears to play an important role in the invasiveness of tumor cells through the basement membrane and into the extracellular matrix. Recent cloning of the heparanase gene and generation of monoclonal antibodies against the enzyme permit to examine tumor cell expression of the enzyme. The aim of the present study was to assess heparanase activity and localization in various subtypes of epithelial ovarian cancer in correlation with oncogene expression. Histologically confirmed malignant ovarian tissue from ten women and tissue from 2 benign ovarian tumors and 4 normal ovaries were assessed for heparanase presence, activity and localization, incidence of apoptosis and expression of the oncogenes erbB2 and Mdm2. Heparanase immunohistostaining and activity were present in mucinous carcinomas and were more intense than in endometrioid and in serous carcinomas. The lowest activity was observed in benign ovarian tumors and normal ovaries. In ovarian carcinomas the enzyme was intensely concentrated in the cytoplasm of the cancerous cells. In contrast, in normal ovaries and benign tumors the enzyme was predominantly localized in endothelial cells lining blood capillaries. The rate of apoptosis was considerably higher in mucinous and endometrioid carcinomas, and was lower in serous and primary peritoneal carcinomas. Extremely high concentration of heparanase was often demonstrated in apoptotic cells. Endometrioid and serous carcinomas showed high expression of Mdm2 and erbB2 while mucinous carcinomas showed low expression. In benign ovarian tumors and normal ovaries the expression of both oncoproteins was extremely low. In conclusion ovarian carcinomas demonstrate higher levels of heparanase than benign tumors and normal ovaries suggesting that the enzyme may play an important role in metastatic spread of the cancerous cells. Apoptosis may be a significant part of the mechanism of the enzyme release into the extracellular space. Although heparanase activity seems to play an essential role in tumor progression, expression of oncogenes, such as erbB2 and Mdm2 seems to play the dominant role in the development of ovarian cancer.     

导入H—ras癌基因后肝癌细胞转移特性的变化

目的探讨Ｈ－ｒａｓ癌基因与肝癌细胞转移行为的关系。方法应用磷酸钙转染法将Ｈ－ｒａｓ癌基因导入人肝癌细胞株ＳＭＭＣ７７２１,通过进行粘附试验、运动试验、Ⅳ型胶原酶（ｃⅣａｓｅ）的分泌、表皮生长因子受体（ＥＧＦＲ）的表达等转移相关指标的测定,观察转染前后细胞转移特性的变化。结果转染Ｈ－ｒａｓ的ＳＭＭＣ７７２１细胞对胞外基质成分层粘连蛋白（ＬＮ）、纤维粘连蛋白（ＦＮ）的粘附能力提高,细胞的运动能力增强,ｃⅣａｓｅ的分泌明显增加,ＥＧＦＲ表达有中等程度的增加,且上述变化与Ｈ－ｒａｓ癌基因的蛋白产物ｐ２１的表达有明确的相关关系。结论Ｈ－ｒａｓ癌基因能在体外诱导人肝癌细胞的转移表型的产生,提高肝癌细胞的转移潜能。     

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.     

Multiple effects on drug-sensitivity, genome stability and malignant potential by combinations of h-ras, C-myc and mutant p53 gene overexpression

Activation of specific oncogenes and inactivation of tumor suppressor genes play major roles in mechanisms leading to neoplastic transformation. The potential involvement of these genes in determining genome stability is an important issue. To examine the relationships between altered oncogene expression and the effects on genome stability, we have investigated the drug sensitivity properties of mouse 10T1/2 fibroblasts transfected with combinations of H-ras, c-myc and the proline 193 mutant form of p53. The relative colony forming efficiencies of these cells were investigated in the absence or presence of various concentrations of the chemotherapeutic agents, methotrexate, N-(phosphonacetyl)-L-aspartate (PALA) or hydroxyurea. The effects of altered oncogene expression were found to be drug and locus specific, and to lead to increased drug resistance (e.g. H-ras transfectants were significantly resistant to methotrexate or PALA), decreased drug resistance (e.g. H-ras/-myc transfectants were significantly less resistant to PALA or hydroxyurea than H-ras transfected cells), or to no significant change in drug sensitivity (e.g. H-ras transfected cells were not significantly different in sensitivity to hydroxyurea than non-transfected cells). Gene amplification was an important but not the only mechanism for drug resistance. Cells that were transfected with p53 (H-ras/p53 or H-ras/c-myc/p53) exhibited the greatest drug resistance properties with all three chemotherapeutic agents, in keeping with the important role of p53 in DNA repair and DNA amplification mechanisms. Although both H-ras/p53 and H-ras/c-myc/p53 groups exhibited very similar genome stability characteristics as determined by drug sensitivity results, they were significantly different in their abilities to produce transformed foci in vitro and lung metastases in vivo. The H-ras/c-myc/p53 transfected cells formed significantly higher numbers of transformed foci and exhibited a greater malignant potential. These results are consistent with observations that H-ras expression directly correlates with malignant potential, and that H-ras/c-myc/p53 transfected cells have higher H-ras expression than H-ras/p53 transfected cells. Alterations in genomic integrity through changes in onocogene expression play important roles in mechanisms determining drug sensitivity; in addition to genome destabilization, other events are critically involved in regulating transformed and malignant characteristics.     

Activation of H-ras oncogenes in preneoplastic mouse mammary tissues

The mammary hyperplastic outgrowth (HOG) line C4, resulted from serial transplantation of a hyperplastic alveolar nodule which arose in a dimethylbenz(a)anthracene (DMBA) treated mouse. The immortalized C4 outgrowth line, on transplantation into syngeneic mice, develops as preneoplastic, hyperplastic outgrowths and subsequently into malignant carcinomas after a long latent period (greater than 6 months). Treatment of mice carrying C4 HOG transplants with DMBA resulted in a reduced latent period for tumor development (less than 3 months) and an increased tumor incidence. DNA's from C4 HOGs and mammary carcinomas of untreated as well as DMBA-treated mice were analyzed for the presence of oncogenes by the NIH3T3 focus forming assay. Transforming H-ras genes were detected in two of 6 preneoplastic HOGs and 10 of 12 carcinomas from DMBA-treated mice. DNAs from neither the HOGs nor the tumors from untreated mice were positive in this assay. The H-ras locus was then directly examined in the 61st codon by in vitro amplification of each of the tissue DNAs using PCR. The location of the activating mutation was determined by hybridization of amplified DNA to mixed sequence oligonucleotide probes. The specific nature of the mutation was defined by RFLPs using XbaI, TaqI and Sau96I restriction enzymes. Six of the H-ras oncogenes in DMBA-promoted tumors were activated by commonly observed A to T transversions at the 61st codon, while five (including an additional tumor with H-ras oncogene revealed by PCR analysis) contained novel A to G transitions. The H-ras oncogene in one DMBA-treated HOG sample was activated by A to T while the second contained an A to G mutations, representative of both modes of mutational activation involved in this model of mammary tumorigenesis. In summary, DMBA-induced point mutated H-ras oncogenes appear to potentiate the progression of hyperplastic outgrowths (HOG) to mammary carcinomas.     

Different metastatic potentials of ras- and src-transformed BALB/c 3T3 A31 variant cells

The metastatic phenotype of tumor cells is thought to be induced by an aberrant signaling cascade or cascades that are different from those required for tumorigenicity. Oncogene-transfected cells with different tumorigenicities and metastatic potentials have been used to identify such pathways and responsible molecules. However, oncogenes that can induce tumorigenicity in recipient cells also frequently induce the metastatic phenotype at the same time. The difficulty in obtaining cell lines that are tumorigenic but not metastatic has hampered such studies. In this report, we transfected the activated c-Ha-ras oncogene into BALB/c 3T3 A31 variant cells and found that the transfectants were tumorigenic but they did not form metastatic lung nodules in the experimental metastasis assay. The phenotype was very stable and was maintained during cultivation. On the other hand, the metastatic potentials of either the transfected cells or the original variant cells could be induced by transfection of the v-src oncogene. The src transfectants formed extensive nodules in lung when injected into the tail veins of congeneric mice. The cell motility of the metastatic src transfectants on Matrigel-coated dishes was greater than that of the ras transfectants. The src transfectants were also invasive in Matrigel when analyzed on a filter. These variant cells transformed by the ras and src oncogenes will be a useful system for identifying the signaling cascades responsible for the metastatic potential of tumors. © 1996 Wiley-Liss, Inc.     

NIH3T3 fibroblasts transformed by the dbl oncogene show altered expression of bradykinin receptors: effect on inositol lipid turnover

We have examined polyphosphoinositide turnover in mouse fibroblasts (NIH3T3) transformed by the dbl oncogene as compared to normal cells. The dbl-transformed fibroblasts did not show alterations of the basal level of inositol polyphosphates, polyphosphoinositides, diacylglycerol or phosphatidic acid. This indicates that the activity of C-type phospholipases, inositol lipid kinases and diacylglycerol kinase is not altered in dbl-induced transformation. However, dbl-transformed NIH3T3 cells exhibited increased inositol lipid turnover in response to bradykinin. Further analysis revealed significantly higher number of bradykinin receptors in dbl transfectants as compared to control NIH3T3. When several clonally-derived dbl NIH3T3 transfectants were analyzed, we observed a large variation of their bradykinin receptor number. Cell lines exhibiting increased bradykinin binding, however, failed to show augmented mitogenic response to the peptide agonist. Among other oncogenes, only ras showed a similar effect. We conclude that increased bradykinin receptor number is a phenomenon observed with several cell lines transformed by different oncogenes, and it does not correlate with either enhanced mitogenic responsiveness of transformed cells to the peptide, or with the presence of a specific oncogene in the transformant.     

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.     

Human Harvey-ras is biochemically different from Kirsten- or N-ras

The biochemical effects of the human H-, N- and K-ras oncogenes were studied. We analysed the induction of c-fos mRNA and protein by the protein kinase C (PKC) activator 12-O-tetradecanoyl-phorbol-13-acetate (TPA) in exponentially growing NIH3T3 fibroblasts transformed by transfection with ras oncogenes. We found that H-ras has the unique ability to inhibit c-fos induction by TPA. In contrast, normal c-fos expression was induced by TPA in fibroblasts transformed by N- or K-ras or by the ras-unrelated oncogenes dbl and trk. The inhibition of c-fos induction by H-ras was not due to alteration in the binding of TPA to the transformed cells or to the selection of idiosyncratic clones. These results provide clear evidence that H-ras is functionally different from K- or N-ras.