Nonfunctional epidermal growth factor receptor in cells transformed by Kirsten sarcoma virus

The cell membrane receptor for epidermal growth factor (EGF) appears to be a glycoprotein of Mr 170,000 and mediates the mitogenic and metabolic responses of cells with EGF receptors (EGF-R). Normal rat kidney (NRK) have about 3 X 10(5) EGF-R per cell. Upon transformation of NRK cells by Kirsten sarcoma virus, the transformed derivative (KNRK) loses the ability to bind 125I-EGF. Membranes from NRK and KNRK cells were included in EGF-dependent phosphorylation reactions to search for evidence of the EGF-R. A phosphorylated protein of Mr 170,000 was detected in both NRK and KNRK membranes. The Mr 170,000 protein was identified to be EGF-R by immunoprecipitation with monoclonal antibody to the receptor. Furthermore, two-dimensional peptide mapping using trypsin and chymotrypsin digestions of the iodinated receptors from both NRK and KNRK cells showed essentially identical patterns. These data indicate that the EGF-R is present in KNRK cells with apparently the same protein structure as the NRK counterpart.     

Epidermal growth factor receptor metabolism and protein kinase activity in human A431 cells infected with Snyder-Theilen feline sarcoma virus or harvey or Kirsten murine sarcoma virus.

When human A431 cells, which carry high numbers of epidermal growth factor (EGF) receptors, are exposed to EGF, the total content of phosphotyrosine in cell protein is increased, the EGF receptor becomes phosphorylated at tyrosine, and new phosphotyrosine-containing 36,000- and 81,000-dalton proteins are detected. We examined the properties of A431 cells infected with Snyder-Theilen feline sarcoma virus, whose transforming protein has associated tyrosine protein kinase activity, and Harvey and Kirsten sarcoma viruses, whose transforming proteins do not. In all cases, the infected cells were more rounded and more capable of anchorage-independent growth than the uninfected cells. EGF receptors were assayed functionally by measuring EGF binding and structurally by metabolic labeling and immunoprecipitation. In no case did infection appear to alter the rate of EGF receptor synthesis, but infection reduced EGF receptor stability by about 50% for cloned Harvey sarcoma virus-infected cells and by 80% for cloned feline sarcoma virus-infected cells. The corresponding reductions in EGF binding were 70 and 90%, respectively. The proteins of feline sarcoma virus-infected A431 cells contained an increased amount of phosphotyrosine, and the 36,000- and 81,000-dalton phosphoproteins were detected. The EGF receptor was not detectably phosphorylated at tyrosine, however, unless the cells were exposed to EGF. The Harvey and Kirsten sarcoma virus-infected cells did not exhibit elevated levels of phosphotyrosine either in the total cell proteins or in the EGF receptor, nor were the 36,000- and 81,000-dalton proteins detectable. However, these phosphoproteins were found in the infected cells after EGF treatment. Thus, all of the infected A431 cells exhibited reduced EGF binding and increased degradation of EGF receptors, yet their patterns of protein phosphorylation were distinct from those of EGF-treated A431 cells.     

Transforming growth factors released from Kirsten sarcoma virus transformed cells do not compete for epidermal growth factor membrane receptors

Kirsten murine sarcoma virus (KiMSV)-transformed rat kidney cells (KNRK) release small polypeptides (Mr 12,500-15,300) into the culture medium that are capable of stimulating normal rat kidney cells (NRK) to form colonies in soft agar. The transforming growth factors (TGFs) did not compete with epidermal growth factor (EGF) for its receptor and did not induce specific phosphorylation of EGF receptor on NRK cell membranes. These properties differ from the TGFs isolated by other investigators. Our data further establish the heterogeneity of the materials produced by transformed cells that induce transformation-specific changes in normal cells.     

Bifunctional activity of transforming growth factor type beta on the growth of NRK-49F cells, normal and transformed by Kirsten murine sarcoma virus

Transformation of rat NRK-49F cells (49F) by Kirsten murine sarcoma virus (Ki-MSV) renders these cells (Ki-49F cells) capable of autonomous anchorage independent (AI) growth. As compared to nontransformed 49F cells, the transformation by Ki-MSV does not modify the cell response to transforming growth factor-beta (TGF-beta) in monolayer conditions, but alters it in A I growth conditions. The growth of nontransformed or Ki-MSV-transformed adherent 49F cells is slowed down by porcine TGF-beta, and this effect is reversed by epidermal growth factor (EGF). This decrease in the cell growth rate, induced by TGF-beta, does not affect the cloning efficiency of untransformed and transformed adherent 49F cells. Contrarily, porcine TGF-beta decreases the A I cloning efficiency of Ki-49F cells in agar-gelled medium; this effect is only partly reversed by EGF, which does not synergise with TGF-beta to enhance the A I growth as in the case of untransformed 49F cells. Media conditioned by 49F cells, Ki-49F cells, and chicken embryo fibroblasts contain a latent TGF-beta whose capacity to promote the A I growth of 49F cells and to inhibit that of Ki-49F cells is unmasked by acidification. The same situation exists concerning TGF-beta from human platelets. Neutral extracts are inefficient in both tests of promotion and inhibition of A I growth and contain an acid-activable component with an apparent molecular weight of 600 kd. In acid extracts, a 5-9 kd apparent molecular weight component is responsible for the A I growth enhancement of 49F cells and the A I growth inhibition of Ki-49F cells. Further purification by reverse phase chromatography shows that both activities strictly coelute at the same point (32%) of an acetonitrile gradient. These results indicate that TGF-beta is present in physiological conditions as a latent form which requires activation for inhibiting the A I growth of transformed cells as well as for enhancing that of 49F cells.     

Absence of evidence for epidermal growth factor receptor and human homolog of the Kirsten rat sarcoma-2 virus oncogene mutations in breast cancer

Aims: The epidermal growth factor receptor (EGFR) is an available target of effective anti-EGFR therapy for human breast cancer. KRAS, the human homolog of the Kirsten rat sarcoma-2 virus oncogene, encodes a main downstream signaling molecule in the EGFR pathway. The aim of this study was to assess the presence of EGFR and KRAS gene mutations in breast cancer. Materials and methods: EGFR and KRAS gene mutations were investigated in formalin-fixed, paraffin-embedded tissues from 143 Chinese female patients with breast cancer by means of real-time quantitative polymerase chain reaction (RT-PCR). Results: Based on RT-PCR, 2/143 (1.4%) samples and 1/143 (0.7%) had EGFR and KRAS gene mutations, respectively. Overall, none of the cases was identified with mutations of both of these two genes. Conclusions: In this study, both EGFR and KRAS mutations were present rarely in this cohort of samples with breast cancer. This suggested that mutation analyses for EGFR and KRAS are not useful as screening tests for sensitivity to anti-EGFR therapy for breast carcinomas.     

Morphological transformation of cells induced by Kirsten sarcoma virus transforming factor is independent of serine protease

Reports from several laboratories have suggested that the virus transformed state may be maintained either by ectopically produced growth factors of alternatively by ectopically produced serine proteases including plasminogen activator. Here we show that the maintenance of transformation induced by Kirsten sarcoma virus induced growth factor(s) is independent of serine proteases in that (1) the factors are not themselves serine proteases, and (2) the growth factors do not induce the expression of detectable serine proteases or plasminogen activator.     

Similarities and differences between the effects of epidermal growth factor and Rous sarcoma virus

We have derived a line of A431 human tumor cells infected with Rous sarcoma virus (RSV). The infected cells contain the RSV-transforming protein, pp60src, which has characteristic tyrosine specific protein kinase activity. As in other RSV-transformed cells, a 36,000-dalton protein is phosphorylated in RSV-infected A431 cells. Addition of epidermal growth factor (EGF) to the cells induces further phosphorylation of this protein. In contrast, this phosphoprotein is not detected in uninfected A431 cells, except when treated with EGF. Increased phosphorylation of the EGF receptor protein and of an 81,000- dalton cellular protein is dependent upon addition of EGF to the culture fluids, in both control and RSV-infected A431 cells. The results are discussed with reference to the similarities and differences between the tyrosine-specific protein kinases induced by RSV and activated by EGF.     

Changes in cellular gene expression in rat thyroid epithelial cells transformed by the Kirsten murine sarcoma virus

We have exploited a recently characterized system of rat thyroid epithelial cells transformed by the wild-type (wt) and a temperature-sensitive (ts) mutant strain of the Kirsten murine sarcoma virus (Ki-MSV) in order to study the effects of the K-ras oncogene on the gene expression of differentiated thyroid epithelial cells. By using cDNAs isolated from normal thyroid glands as probes, we were able to identify three sets of cellular sequences whose expression is influenced by the v-K-ras oncogene. The first set of genes is irreversibly repressed by transformation with both the wt and the ts viruses. The second set of genes is repressed in the ts-Ki-MSV-transformed cells but not in the same cells grown at the nonpermissive temperature. A third set of genes is present at higher levels at the nonpermissive temperature than at the permissive temperature. This system has allowed us to isolate and characterize a number of cDNA clones belonging to each of these three sets of genes. These specific cDNAs are suitable probes to study phenotypical changes during transformation of epithelial cells.     

Mouse and rat cells undergo rapidly inducible changes in polypeptide secretion following infection with Kirsten murine sarcoma virus

Characteristic changes in the secreted polypeptides of Kirsten murine sarcoma virus (KiMSV) transformed mouse and rat cell lines could be detected 48 hours after infection of phenotypically normal cells with this virus and correlated with detection of the KiMSV encoded polypeptide p21.     

Presence of a Kirsten murine sarcoma virus ras oncogene in cells transformed by 3-methylcholanthrene.

Oncogenes have previously been reported in the DNAs of mouse fibroblast lines which had become transformed after in vitro exposure to the carcinogen 3-methylcholanthrene. These oncogenes are now shown to be versions of the cellular Kirsten ras gene and are therefore homologous to oncogenes detected in a variety of human tumor DNAs.     

Cellular proliferation kinetics of the murine sarcoma induced by the Moloney sarcoma virus

Abstract. Cell proliferation kinetics of the sarcoma induced by Moloney virus was studied in newborn Swiss OFl mice.
After in vivo injection of tritiated thymidine, followed by autoradiography, it was shown that the majority of cells were actively proliferating (labelling index; 31%, growth fraction 78%). The mean cell cycle was 16 hr and cell loss was relatively low (cell loss factor 48%). The study of tumour specific activity with time after a single [ in vivo ] injection of [³H]dR or [¹²⁵I]UdR did not demonstrate the same degree of cell loss as that calculated by autoradiography. This result is consistent with a massive reutilization of radioactivity released by normal tissues.     

Separation of the transforming growth factor from cells of murine sarcoma induced by polymeric film

Use was made of the cell line PS-103 induced by subcutaneous implantation of plastic film to CBA mice. The conditioned medium from PS-103 was shown to stimulate anchorage independence of PS-103 itself and several pseudonormal cells: NRK and NIH/3T3. The peak of the colony-stimulating activity after gel filtration was displayed by fractions with a molecular weight of 15 000, which were acid- and heat-resistant. All those characteristics correlated with the traits of the transforming growth factors (TGF). The significance of the TGF for carcinogenesis induced by plastic films is discussed.     

Platelet-derived growth factor-stimulated migration of murine fibroblasts is associated with epidermal growth factor receptor expression and tyrosine phosphorylation

Previous studies have shown that epidermal growth factor (EGF) synergizes with various extracellular matrix components in promoting the migration of B82L fibroblasts expressing wild-type EGF receptors and that functional EGF receptors are critical for the conversion of B82L fibroblasts to a migratory cell type (). In the present study, we examined the effects of platelet-derived growth factor (PDGF) on the motility of B82L fibroblasts using a microchemotaxis chamber. We found that PDGF can enhance fibronectin-induced migration of B82L fibroblasts expressing wild-type EGF receptors (B82L-clone B3). However, B82L cells that lack the EGF receptor (B82L-parental) or that express an EGF receptor that is kinase-inactive (B82L-K721M) or C-terminally truncated (B82L-c'973) exhibit little PDGF-stimulated migration. In addition, none of these three cell lines exhibit the capacity to migrate to fibronectin alone. These observations indicate that, similar to cell migration toward fibronectin, PDGF-induced cell migration of B82L fibroblasts is augmented by the expression of an intact EGF receptor kinase. The loss of PDGF-stimulated motility in B82L cells that do not express an intact EGF receptor does not appear to result from a gross dysfunction of PDGF receptors, because ligand-stimulated tyrosine phosphorylation of the PDGF-beta receptor and the activation of mitogen-activated protein kinases are readily detectable in these cells. Moreover, an interaction between EGF and PDGF receptor systems is supported by the observation that the EGF receptor exhibits an increase in phosphotyrosine content in a time-dependent fashion upon the addition of PDGF. Altogether, these studies demonstrate that the expression of EGF receptor is critical for PDGF-stimulated migration of murine B82L fibroblasts and suggest a role for the EGF receptor downstream of PDGF receptor activation in the signaling events that lead to PDGF-stimulated cell motility.     

Suppression of protein tyrosine kinase activity of the epidermal growth factor receptor by epidermal growth factor

Epidermal growth factor (EGF) receptor protein kinase activity, estimated by the use of peptide substrates, was reduced by as much as 70% after the treatment of intact A431 human carcinoma cells with EGF. The apparent decrease in protein kinase activity was observed after immunoprecipitation of the receptor or after purification of the receptor by lectin chromatography. By the use of [35S]methionine, it was determined that the total amount of receptor obtained was the same whether or not cells were treated with EGF. EGF stimulated the purified receptor protein kinase activity in vitro; however, the EGF-stimulated activity of receptor from EGF-treated cells continued to be reduced by as much at 70% compared to the EGF-stimulated activity from untreated cells. The reduction in receptor protein kinase activity induced by EGF may represent a feedback mechanism by which responsiveness to the growth factor is regulated.     

In vivo modulation of epidermal growth factor receptor phosphorylation in mice expressing different gangliosides

We studied in this work the in vivo phosphorylation of the epidermal growth factor receptor (EGFr) in skin from knockout mice lacking different ganglioside glycosyltransferases. Results show an enhancement of EGFr phosphorylation, after EGF stimulation, in skin from Sial-T2 knockout and Sial-T2/GalNAc-T double knockout mice as compared with wild-type and Sial-T1 knockout mice. Qualitative analysis of ganglioside composition in mice skin suggest that the increase of EGFr phosphorylation observed in skin from Sial-T2 knockout and Sial-T2/GalNAc-T double knockout mice in response to EGF might not be primary attributed to the expression of GD3 or a-series gangliosides in mice skin. These studies provide, for the first time, an approach for studying the molecular mechanisms involved in the in vivo regulation of EGFr function by gangliosides.