Platelet-derived growth factor stimulation of GTPase-activating protein tyrosine phosphorylation in control and c-H-ras-expressing NIH 3T3 cells correlates with p21ras activation.

Platelet-derived growth factor (PDGF) stimulation of NIH 3T3 cells leads to the rapid tyrosine phosphorylation of the GTPase-activating protein (GAP) and an associated 64- to 62-kDa tyrosine-phosphorylated protein (p64/62). To assess the functions of these proteins, we evaluated their phosphorylation state in normal NIH 3T3 cells as well as in cells transformed by oncogenically activated v-H-ras or overexpression of c-H-ras genes. No significant GAP tyrosine phosphorylation was observed in unstimulated cultures, while PDGF-BB induced rapid tyrosine phosphorylation of GAP in all cell lines analyzed. In NIH 3T3 cells, we found that PDGF stimulation led to the recovery of between 37 and 52% of GAP molecules by immunoprecipitation with monoclonal antiphosphotyrosine antibodies. Furthermore, PDGF exposure led to a rapid and sustained increase in the levels of p21ras bound to GTP, with kinetics similar to those observed for GAP tyrosine phosphorylation. The PDGF-induced increases in GTP-bound p21ras in NIH 3T3 cells were comparable to the steady-state level observed in serum-starved c-H-ras-overexpressing transformants, conditions in which these cells maintained high rates of DNA synthesis. These results imply that the level of p21ras activation following PDGF stimulation of NIH 3T3 cells is sufficient to support mitogenic stimulation. Addition of PDGF to c-H-ras-overexpressing cells also resulted in a rapid and sustained increase in GTP-bound p21ras. In these cells GAP, but not p64/62, showed increased tyrosine phosphorylation, with kinetics similar to those observed for increased GTP-bound p21ras. All of these findings support a role for GAP tyrosine phosphorylation in p21ras activation and mitogenic signaling.     

Inhibition of NIH 3T3 cell proliferation by a mutant ras protein with preferential affinity for GDP.

Substitution of asparagine for serine at position 17 decreased the affinity of rasH p21 for GTP 20- to 40-fold without significantly affecting its affinity for GDP. Transfection of NIH 3T3 cells with a mammalian expression vector containing the Asn-17 rasH gene and a Neor gene under the control of the same promoter yielded only a small fraction of the expected number of G418-resistant colonies, indicating that expression of Asn-17 p21 inhibited cell proliferation. The inhibitory effect of Asn-17 p21 required its localization to the plasma membrane and was reversed by coexpression of an activated ras gene, indicating that the mutant p21 blocked the endogenous ras function required for NIH 3T3 cell proliferation. NIH 3T3 cells transformed by v-mos and v-raf, but not v-src, were resistant to inhibition by Asn-17 p21, indicating that the requirement for normal ras function can be bypassed by these cytoplasmic oncogenes. The Asn-17 mutant represents a novel reagent for the study of ras function by virtue of its ability to inhibit cellular ras activity in vivo. Since this phenotype is likely associated with the preferential affinity of the mutant protein for GDP, analogous mutations might also yield inhibitors of other proteins whose activities are regulated by guanine nucleotide binding.     

Lipid signalling pathways in normal and ras-transfected NIH/3T3 cells

The role of ras oncogenes in cellular signalling pathways involving phospholipid breakdown was studied in untransfected and proto-H-ras and mutated H-, K- and N-ras transfected NIH/3T3 cells. When the cells were grown at low cell densities, all of the ras transfected cells had 2-4 fold higher diacylglycerol (DAG) levels compared to growing NIH/3T3 cells. At high cell densities, DAG levels decreased in the former and increased in contact inhibited NIH/3T3 cells. In this regard, only cells transformed by mutated cellular and viral H-ras oncogenes (but not by the H-ras proto-oncogene) had elevated DAG levels compared to contact inhibited NIH/3T3 cells. The basal levels of inositol phosphates in ras transfected cells were not significantly different from NIH/3T3 cells and did not vary with cell density. Thus, the elevated DAG levels are not a consequence of increased phosphoinositide hydrolysis. The latter was stimulated by serum and bombesin only in normal and proto-H-ras transfected cells. In contrast, stimulation by bradykinin was observed only in cells transformed by mutated cellular ras oncogenes. Furthermore, aluminum fluoride stimulated phosphoinositide breakdown in the latter cells indicating that there was no uncoupling of the G protein from phospholipase C. Treatment of ras transfected cells with dibutyryl cyclic AMP (DB-cAMP), which causes an inhibition of growth and a reversal of the transformed morphology, did not alter the basal levels of inositol phosphates, DB-cAMP, however, did lower DAG levels in some of the transformed cell lines, but elevated DAG levels in low density NIH/3T3 cells. These findings indicate that the ras gene product p21 is not involved in phosphoinositide hydrolysis and that DAG levels do not correlate with cell growth in either normal or ras transfected NIH/3T3 cells. Thus, p21 appears to alter cell growth through mechanism(s) independent of lipid signalling pathways.     

Increased tyrosine phosphorylation in ras transformed fibroblasts occurs prior to manifestation of the transformed phenotype

Murine fibroblasts transformed by ras oncogenes exhibited an increased amount of tyrosine phosphorylated proteins compared to normal cells. The pattern of phosphorylation was similar to that observed in cells chronically stimulated with EGF or PDGF, and is probably due to autocrine stimulation of receptor tyrosine kinases. NIH 3T3 cells transfected with H-ras under the control of a glucocorticoid inducible promoter were used to determine the temporal relationship among expression of p21H-ras oncoprotein, increase in tyrosine phosphorylation and appearance of the transformed morphology. Enhanced tyrosine phosphorylation was observed more than 24 hours before evidence of morphological changes. These results suggest that full transformation by ras oncogenes requires cooperation with tyrosine protein kinases.     

Development and analysis of a transformation-defective mutant of Harvey murine sarcoma tk virus and its gene product.

The Harvey murine sarcoma virus has been cloned and induces focus formation on NIH 3T3 cells. Recombinants of this virus have been constructed which include the thymidine kinase gene of herpes simplex virus type 1 in a downstream linkage with the p21 ras gene of Harvey murine sarcoma virus. Harvey murine sarcoma tk virus rescued from cells transfected with this construct is both thymidine kinase positive and focus inducing in in vitro transmission studies. The hypoxanthine-aminopterin-thymidine selectability of the thymidine kinase gene carried by this virus has been exploited to develop three mutants defective in the p21 ras sequence. All three are focus negative and thymidine kinase positive when transmitted to suitable cells. Of these, only one encodes a p22 that is immunologically related to p21. This mutant has been used to explore the relationship between the known characteristics of p21 and cellular transformation. Data presented herein indicate that the p21 of Harvey murine sarcoma virus consists of at least two domains, one which specifies the guanine nucleotide-binding activity of p21 and the other which is involved in p21-membrane association in transformed cells.     

Two dominant inhibitory mutants of p21ras interfere with insulin-induced gene expression.

Insulin induces a rapid activation of p21ras in NIH 3T3 and Chinese hamster ovary cells that overexpress the insulin receptor. Previously, we suggested that p21ras may mediate insulin-induced gene expression. To test such a function of p21ras more directly, we studied the effect of different dominant inhibitory mutants of p21ras on the induction of gene expression in response to insulin. We transfected a collagenase promoter-chloramphenicol acetyltransferase (CAT) gene or a fos promoter-luciferase gene into NIH 3T3 cells that overexpressed the insulin receptor. The activities of both promoters were strongly induced after treatment with insulin. This induction could be suppressed by cotransfection of two inhibitory mutant ras genes, H-ras(Asn-17) or H-ras(Leu-61,Ser-186). In particular, insulin-induced activation of the fos promoter was inhibited completely by H-ras(Asn-17). These results show that p21ras functions as an intermediate in the insulin signal transduction route leading to the induction of gene expression.     

A transforming ras gene can provide an essential function ordinarily supplied by an endogenous ras gene.

Microinjection of monoclonal antibody Y13-259, which reacts with all known mammalian and yeast ras-encoded proteins, has previously been shown to prevent NIH 3T3 cells from entering the S phase (L. S. Mulcahy, M. R. Smith, and D. W. Stacey, Nature [London] 313:241-243, 1985). We have now found several transformation-competent mutant v-rasH genes whose protein products in transformed NIH 3T3 cells are not immunoprecipitated by this monoclonal antibody. These mutant proteins are, however, precipitated by a different anti-ras antibody. Each of these mutants lacks Met-72 of v-rasH. In contrast to the result for cells transformed by wild-type v-rasH, Y13-259 microinjection of NIH 3T3 cells transformed by these mutant ras genes did not prevent the cells from entering the S phase. These results imply that a transformation-competent ras gene can supply a normal essential function for NIH 3T3 cells. When the proteins encoded by the mutant ras genes were overproduced in Escherichia coli, several mutant proteins that lacked Met-72 failed to bind Y13-259 in a Western blot. However, a ras protein from a mutant lacking amino antibody, but a ras protein from a mutant lacking amino acids 72 to 84 did not. These results suggest that Y13-259 may bind to a higher ordered structure that has been restored in the mutant lacking amino acids 72 to 82.     

Reversal of transformed phenotype by monoclonal antibodies against Ha-ras p21 proteins

The transforming activities of p21 ras proteins have been determined by micro-injection of these proteins into NIH3T3 cells. In order to facilitate functional studies on the effect of ras proteins on malignant transformation and normal cellular growth, analysis has been made with three monoclonal antibodies (YA6-172, Y13-238 and Y13-259) as originally reported by Furth et al. (J virol 43 (1982) 294). Purified immunoglobulin of Y13-259 has the highest titer of binding to bacterially synthesized p21 ras proteins. Experimental analyses indicate that only Y13-259 antibody will neutralize the transforming activity of the co-injected bacterially synthesized ras protein and the neutralization effect was blocked by co-injection of excess ras protein. In addition, micro-injection of Y13-259 immunoglobulin into transformed NIH3T3 cells (obtained by DNA transfection of NIH3T3 cells with molecularly cloned ras gene) reversed their transformed phenotypes. These results indicate that both bacterially synthesized p21 ras proteins and the natural ras proteins produced in NIH3T3 cells were neutralized by Y13-259 antibody.     

Plasma membrane-targeted ras GTPase-activating protein is a potent suppressor of p21ras function.

Although p21ras is localized to the plasma membrane, proteins it interacts with, such as the GTPase-activating proteins (GAPs) ras GAP and neurofibromin (NF1), are not, suggesting that one function of p21ras GTP may be to target such proteins to the plasma membrane. To investigate the effects of targeting ras GAP to the plasma membrane, ras C-terminal motifs sufficient for plasma membrane localization of p21ras were cloned onto the C terminus of ras GAP. Plasma membrane-targeted ras GAP is growth inhibitory to NIH 3T3 fibroblasts and COS cells. This growth inhibition correlates with GAP catalytic activity, since the plasma membrane-targeted C-terminal catalytic domain or the GAP-related domain of neurofibromin is inhibitory, whereas the similarly targeted N-terminal domain is not. Moreover, the inhibition is abrogated by the inactivating mutation L902I, which abolishes ras GAP catalytic activity. Coexpression of oncogenic mutant ras rescues cell viability, but the majority of rescued colonies are phenotypically untransformed. Furthermore, in focus assays, targeted ras GAP suppresses transformation by oncogenic mutant ras, and in reversion assays, targeted ras GAP can revert cells transformed by oncogenic mutant ras. Neither the targeted or nontargeted N-terminal domain nor the L902I mutant of ras GAP has any transforming activity. These data demonstrate that ras GAP can function as a negative regulator of ras and that plasma membrane localization potentiates this activity. However, if ras GAP is involved in the effector functions of p21ras, it can only be part of the effector complex for cell transformation.     

Down-modulation of an oncogene protein product and reversion of the transformed phenotype by monoclonal antibodies

Exposure of neu-oncogene-transformed NIH 3T3 cells to monoclonal antibodies reactive with the neu gene product, p185, results in the rapid and reversible loss of both cell-surface and total cellular p185. Although not directly cytotoxic, monoclonal anti-p185 antibody treatment causes neu-transformed NIH 3T3 cells to revert to a nontransformed phenotype, as determined by anchorage-independent growth. Isotype matched control antibodies of an unrelated specificity do not affect p185 levels or colony formation in soft agar by neu-transformed NIH 3T3 cells. Soft agar colony formation by NIH 3T3 cells transformed by ras oncogenes is not affected by anti-p185 antibody treatment. Anchorage-independent growth of cells from the ethylnitrosourea-induced rat neuroblastoma line in which neu was originally detected by DNA transfection is also inhibited in the presence of anti-p185 monoclonal antibodies. Collectively, these results suggest that p185 is required to maintain transformation induced by the neu oncogene.     

Transformation by v-H-ras does not restore proliferation of a set of temperature-sensitive cell-cycle mutants of rat 3Y1 fibroblasts

Three temperature-sensitive cell-cycle mutants of rat 3Y1 fibroblasts (3Y1tsD123, 3Y1tsG125, and 3Y1tsH203, each belonging to distinct complementation groups) were transformed with plasmid DNA carrying Harvey murine sarcoma virus cDNA. The criteria for transformation were increase in saturation cell density, capability to clone in soft agar, and alteration in the cellular morphology. At 39.8 degrees C (restrictive temperature of the parental cell lines), all the transformed sublines of each mutant ceased to proliferate and were arrested reversibly in the G1 phase of the cell cycle like the parental lines. At both 39.8 degrees C and 33.8 degrees C (permissive temperature for the parental lines), all the untransformed parental lines synthesized p21ras at low rate. At 33.8 degrees C, all the transformed sublines synthesized p21ras at much higher rate and expressed the morphological phenotype characteristic to v-H-ras-induced transformation. At 39.8 degrees C, the rate of p21ras synthesis was not changed in the transformed sublines of 3Y1tsD123 and 3Y1tsG125, and the morphology of transformed phenotype also remained intact. In the transformed subline of 3Y1tsH203, the rate of p21ras synthesis was lowered at 39.8 degrees C to that seen in the untransformed parental line, and the transformed phenotype in morphology disappeared. In all of the transformed sublines, the amount of v-H-ras mRNA markedly expressed at both 33.8 degrees C and 39.8 degrees C.(ABSTRACT TRUNCATED AT 250 WORDS)     

The involvement of activated ras genes in determining the transformed phenotype

Activated ras oncogenes have been identified in a wide range of tumours. All examples of ras gene activation in tumours so far result from amino acid substitution at Gly12 or Gln61. To learn more about how mutations in ras genes lead to transformation, we have analysed transforming growth factor production in NIH/3T3 cells transformed by each of the three ras genes. These results show that the transformed phenotype of these cells results from a combination of the presence of the mutant ras protein and TGF alpha production. In a second series of experiments we have shown that the mutation of a ras gene in a tumour cell line can lead to tumour progression towards a more aggressive phenotype.     

Effect of a dominant inhibitory Ha-ras mutation on mitogenic signal transduction in NIH 3T3 cells.

We used a dominant inhibitory mutation of c-Ha-ras which changes Ser-17 to Asn-17 in the gene product p21 [p21(Asn-17)Ha-ras] to investigate ras function in mitogenic signal transduction. An NIH 3T3 cell line [NIH(M17)] was isolated that displayed inducible expression of the mutant Ha-ras gene (Ha-ras Asn-17) via the mouse mammary tumor virus long terminal repeat and was growth inhibited by dexamethasone. The effect of dexamethasone induction on response of quiescent NIH(M17) cells to mitogens was then analyzed. Stimulation of DNA synthesis by epidermal growth factor (EGF) and 12-O-tetradecanoylphorbol-13-acetate (TPA) was completely blocked by p21(Asn-17) expression, and stimulation by serum, fibroblast growth factor, and platelet-derived growth factor was partially inhibited. However, the induction of fos, jun, and myc by EGF and TPA was not significantly inhibited in this cell line. An effect of p21(Asn-17) on fos induction was, however, demonstrated in transient expression assays in which quiescent NIH 3T3 cells were cotransfected with a fos-cat receptor plasmid plus a Ha-ras Asn-17 expression vector. In this assay, p21(Asn-17) inhibited chloramphenicol acetyltransferase expression induced by EGF and other growth factors. In contrast to its effect on DNA synthesis, however, Ha-ras Asn-17 expression did not inhibit fos-cat expression induced by TPA. Conversely, downregulation of protein kinase C did not inhibit fos-cat induction by activated ras or other oncogenes. These results suggest that ras proteins are involved in at least two parallel mitogenic signal transduction pathways, one of which is independent of protein kinase C. Although either pathway alone appears to be sufficient to induce fos, both appear to be necessary to induce the full mitogenic response.     

Plasmid mediated mutagenesis of a cellular gene in transfected eukaryotic cells.

NIH3T3 cells are widely used in transformation assays and readily take up transfected DNA. A system has been devised using NIH3T3 cells to measure the mutagenic effect of transfected DNA on recipient cell genes. NIH3T3 cells can be mutated to 6-thioguanine resistance at a frequency which suggests that at least a portion of the cells have only one functional copy of the HGPRT gene. They have a low spontaneous background mutation frequency (approximately 1 X 10(-7)). Transfection of three different plasmids into NIH3T3 cells induced 6-thioguanine resistant mutants at frequencies ranging from 3 to 11 fold above background. The mutant phenotype is stable and reversion frequencies of several mutants are less than or equal to 1 X 10(-7). Southern blot analysis of the HGPRT gene in several mutants showed that 4 of 26 mutants (15.4%) had detectable alterations in the structure of the HGPRT gene. Interestingly 3 of the 4 mutants showing rearrangements were obtained by transfection of the HSV-2 morphological transforming region.     

Ras p21 proteins with high or low GTPase activity can efficiently transform NIH/3T3 cells

We sought to determine whether decreased in vitro GTPase activity is uniformly associated with ras p21 mutants possessing efficient transforming properties. Normal H-ras p21-[Gly12-Ala59] as well as an H-ras p21-[Gly12-Thr59] mutant exhibited in vitro GTPase activities at least fivefold higher than either H-ras p21-[Lys12-Ala59] or H-ras p21-[Arg12-Thr59] mutants. Microinjection of as much as 6 X 10(6) molecules/cell of bacterially expressed normal H-ras p21 induced no detectable alterations of NIH/3T3 cells. In contrast, inoculation of 4-5 X 10(5) molecules/cell of each p21 mutant induced morphologic alterations and stimulated DNA synthesis. Moreover, the transforming activity of each mutant expressed in a eukaryotic vector was similar and at least 100-fold greater than that of the normal H-ras gene. These findings establish that activation of efficient transforming properties by ras p21 proteins can occur by mechanisms not involving reduced in vitro GTPase activity.     

C127 cells resistant to transformation by tyrosine protein kinase oncogenes

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

Activation of a human c-K-ras oncogene

The human lung carcinomas PR310 and PR371 contain activated c-K-ras oncogenes. The oncogene of PR371 was found to present a mutation at codon 12 of the first coding exon which substitutes cysteine for glycine in the encoded p21 protein. We report here that the transforming gene of PR310 tumor contains a mutation in the second coding exon. An A----T transversion at codon 61 results in the incorporation of histidine instead of glutamine in the c-K-ras gene product. By constructing c-K-ras/c-H-ras chimeric genes we show that this point mutation is sufficient to confer transforming potential to ras genes, and that a hybrid ras gene coding for a protein mutant at both codons 12 and 61 is also capable of transforming NIH3T3 cells. The relative transforming potency of p21 proteins encoded by ras genes mutant at codons 12, 61 or both has been analyzed. Our studies also show that the coding exons of ras genes, including the fourth, can be interchanged and the chimeric p21 ras proteins retain their oncogenic ability in normal rodent established cell lines.     

Resistance to oncogenic transformation in revertant R1 of human ras-transformed NIH 3T3 cells.

A flat revertant, R1, was isolated from human activated c-Ha-ras-1 (hu-ac-Ha-ras) gene-transformed NIH 3T3 cells (EJ-NIH 3T3) treated with mutagens. R1 contained unchanged transfected hu-ac-Ha-ras DNA and expressed high levels of hu-ac-Ha-ras-specific mRNA and p21 protein. Transfection experiments revealed that NIH 3T3 cells could be transformed by DNA from R1 cells but R1 cells could not be retransformed by Kirsten sarcoma virus, DNA from EJ-NIH 3T3 cells, hu-ac-Ha-ras, v-src, v-mos, simian virus 40 large T antigen, or polyomavirus middle T antigen. Somatic cell hybridization studies showed that R1 was not retransformed by fusion with NIH 3T3 cells and suppressed anchorage independence of EJ-NIH 3T3 and hu-ac-Ha-ras gene-transformed rat W31 cells in soft agar. These results suggest that the reversion and resistance to several oncogenes in R1 is due not to cellular defects in the production of the transformed phenotype but rather to enhancement of cellular mechanisms that suppress oncogenic transformation.     

Functional modification of a 21-kilodalton G protein when ADP-ribosylated by exoenzyme C3 of Clostridium botulinum.

Exoenzyme C3 from Clostridium botulinum types C and D specifically ADP-ribosylated a 21-kilodalton cellular protein, p21.bot. Guanyl nucleotides protected the substrate against denaturation, which implies that p21.bot is a G protein. When introduced into the interior of cells, purified exoenzyme C3 ADP-ribosylated intracellular p21.bot and changed its function. NIH 3T3, PC12, and other cells rapidly underwent temporary morphological alterations that were in certain respects similar to those seen after microinjection of cloned ras proteins. When injected into Xenopus oocytes, C3 induced migration of germinal vesicles and potentiated the cholera toxin-sensitive augmentation of germinal vesicle breakdown by progesterone, also as caused by ras proteins. Nevertheless, p21.bot was immunologically distinct from p21ras.