Characterization of activated proto-oncogenes in chemically transformed syrian hamster embryo cells

The Syrian hamster embryo (SHE) cell transformation model has been used by many investigators to study the multistep process of neoplastic transformation induced by chemical carcinogens. In this study we have attempted to determine if activated proto-oncogenes are present in the transformed cells induced by a variety of chemical carcinogens. Twelve carcinogen-induced hamster cell lines, established by treatment of normal SHE cells with benzo[a]pyrene, diethylstilbestrol, or asbestos, were examined. One spontaneously transformed cell line (BHK-A) was also studied. Some of the cell lines were also tested for oncogene activation at the preneoplastic stage, before they acquired tumorigenic potential. DNAs from normal, preneoplastic, and neoplastic cells were tested by transfection into mouse NIH 3T3 cells, and morphologically transformed foci were scored on the contact-inhibited monolayer of 3T3 cells. The frequency of focus formation for normal SHE cell DNA was <0.0008 foci/μg DNA, while approximately 40% (5 of 12) of the DNAs from carcinogen-induced, tumorigenic hamster cell lines induced foci at a frequency of ? 0.012 foci/μg DNA. The other seven carcinogen-induced cell lines and the BHK-A cells were negative (<0.002 foci/μg DNA). When the DNAs from transformed foci induced by the five positive cell lines were retransfected into NIH 3T3 cells, the frequency of secondary foci of 3T3 cells was as much as 50-fold higher (1.34 foci/μg DNA) than with the primary transfectants. DNAs from transformed foci or tumors derived from transformed foci were screened by Southern blot analyses with known oncogenes and with a hamster repetitive DNA probe for the presence of transfected hamster oncogenes. Newly acquired hamster Ha-ras sequences were detected in transformed 3T3 cells induced by four of the five hamster tumor DNAs. Immunoprecipitation of lysates of several secondary transformants with a ras monoclonal antibody (Y13–259) showed altered gel mobility of the p21^ras protein consistent with a mutation at codon 12. These activated ras genes were detected by the NIH 3T3 assay in the tumorigenic hamster cells but not in the preneoplastic, immortal cell from which they were derived. The activated Ha-ras proto-oncogene was detected in cell lines induced by each of the three different carcinogens studied. Cells from transformed foci inauced by DNA from one of the hamster tumor cell lines (BP6T) contained hamster sequences but did not show newly acquired Haras, Ki-ras, or N-ras genes on Southern analysis or altered p21^ras protein. The transforming gene in this cell line appears to be a non-^ras oncogene. These observations indicate that ～40% of the chemically transformed Syrian hamster tumor cell lines have activated Ha-ras oncogenes. The activation of Ha-ras proto-oncogene is a late, postimmortalization step in the neoplastic progression of SHE cells. Only one cell line with a non-^ras oncogene was detected in the NIH 3T3 focus assay, and ～60% of the cell lines were inactive in this assay, indicating the need to develop alternative assay systems for oncogene activation. Some of the preneoplastic Syrian hamster cell lines may be useful for this purpose.     

Transforming activity of DNA from rat liver tumors induced by the carcinogen methyl(acetoxymethyl)nitrosamine

Altered c-Ha-ras genes have been frequently detected in the DNA of spontaneous or chemically induced mouse liver tumors. To determine if ras gene mutation is a frequent event during liver carcinogenesis in rats, we examined the transforming activity of DNA from liver tumors that developed in rats injected with methyl(acetoxymethyl)nitrosamine (DMN-OAc) after a partial hepatectomy. Three weeks after the injection of DMN-OAc, rats were fed a diet containing phenobarbital. This carcinogen acts only on replicating liver cells. Six of eight tumor DNAs induced the transformation of NIH 3T3 cells. The transforming activity was stable upon a second round of transfection, and the transformants were tumorigenic in nude mice. Southern blot analysis of transformant DNAs showed that the transforming activity was not due to the acquisition of a ras (Ha, Ki, or N), neu, myc, A-raf, v-raf, erbA, or erbB gene of rat origin. Several transformants' restriction enzyme sensitivity was analyzed, and their activity indicated that similar transforming sequences were present in at least two tumors and that one tumor contained two different transforming sequences. These results suggest that during hepatocarcinogenesis induced in rats by DMN-OAc, alterations in the ras gene family occur infrequently or not at all and that several different genes (which are not homologous to common oncogenes) become activated and are capable of transforming NIH 3T3 cells.     

Detection of novel non-ras oncogenes in rat nasal squamous cell carcinomas

Rat nasal squamous cell carcinomas induced by inhalation of three direct-acting alkylating agents yielded DNA containing activated oncogenes with no homology to any member of the ras family. The novel NIH 3T3 transforming oncogenes from tumors induced by beta-propiolactone and methylmethane sulfonate are distinct from each other based on restriction analysis. The gene isolated from beta-propiolactone-induced tumors is between 6 and 9 kb in size. None of the tumors induced by dimethylcarbamyl chloride contained positive DNA in the NIH 3T3 focus assay or in the nude mouse cotransfection assay. The rat nasal tumor model is apparently ideally suited for analysis of the roles of carcinogen and tissue specificity in oncogene activation, especially related to novel (non-ras) transforming oncogenes.     

Infrequent activation of K-ras, H-ras, and other oncogenes in hepatocellular neoplasms initiated by methyl(acetoxymethyl)nitrosamine, a methylating agent, and promoted by phenobarbital in F344 rats

Fischer 344/Ncr rats of both sexes were subjected to partial hepatectomy and then initiated 21-24 h later by a single injection of methyl(acetoxymethyl)nitrosamine at 0.1 mmol/kg body weight via the portal vein. Beginning 3 weeks later, development of hepatocellular neoplasms in initiated rats was promoted by feeding 0.05% phenobarbital (PB) in the diet. Not only intrahepatic lesions but also a variety of extrahepatic tumors were induced. High-molecular-weight DNAs were prepared from 67 samples of grossly normal liver containing multiple preneoplastic foci/areas of microscopic dimensions, 137 hepatocellular adenomas (nodules), 93 hepatocellular carcinomas (HCC), 10 cholangiomas, and 25 extrahepatic tumors in 95 rats and tested for transforming activity in the NIH 3T3 transfection assay. DNA preparations from 7 of 93 HCCs, 2 of 10 cholangiomas, 2 of 137 nodules, 1 histiocytic sarcoma, and 1 thyroid carcinoma were positive in the transfection assay. Southern blot analysis showed that NIH 3T3 transformants induced by DNA from 5 HCCs, 1 hepatocellular adenoma, 1 cholangioma, 1 histiocytic sarcoma, and 1 thyroid carcinoma contained an activated K-ras gene of rat origin. Rat-derived H-ras was identified in transformants from 2 additional HCCs and rat c-raf from 1 hepatocellular adenoma. The transforming gene from one cholangioma showed no sequence homology to the ras genes, neu, or c-raf. Immunoprecipitation analysis of ras Mr 21,000 protein in 11 transformants indicated that, based upon protein electrophoretic mobilities, activation of the ras genes consistently resulted from mutations in codon 12 of these genes. Selective oligonucleotide analysis revealed that a G----A transition in the second base of codon 12 of K-ras was present in the 9 K-ras-positive transformants and also in DNAs prepared from the original tumors. In contrast, oligonucleotide hybridization experiments with DNAs from 35 hepatocellular tumors that were negative in transfection assays revealed the presence of mutant K-ras in 1 of 15 HCCs; no mutation could be detected in 20 transfection-negative adenomas. The infrequency of detection of a specific oncogene, more frequent detection of oncogenes in malignant tumors, and failure to observe activated oncogenes in preneoplastic lesions suggest that activation of ras oncogenes may occur as a late and infrequent event in the evolution of some rat hepatocellular neoplasms and that mutation of a specific ras locus is not an obligatory early event in the genesis of these neoplasms.     

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

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

An oncogenic chromosome 8-9 gene fusion isolated following transfection of human ovarian carcinoma cell line DNA

Transfection of NIH3T3 cells with genomic DNA from the human ovarian adenocarcinoma tumor cell line OVCAR-3 identified ovc, a rearranged human DNA sequence which was generated during transfection and which induced both morphological transformation and tumorigenesis. A human alu repeat positive 10.5 kb EcoRI fragment present in all transformants was cloned, and two alu-free fragments of 1.8 kb and 2.2 kb were subcloned. The cloned 10.5 kb fragment is not biologically active in DNA transfection assays. Probe from the 2.2 kb fragment hybridizes to poly A + RNA from the transformants and several human tumor cell lines, including OVCAR-3. The 2.2 kb fragment maps to a site on human chromosome 9 (9p24) not known to contain oncogenic sequences, and identifies a two allele polymorphic restriction site. The 1.8 kb fragment maps to human chromosome 8. The ovc transforming sequences fail to hybridize to probes to any of 14 known oncogenes, indicating that they may represent a previously unknown human transforming gene.     

The Harvey ras 1 gene is activated in papillomavirus-associated carcinomas of the upper alimentary canal in cattle

The possible activation of ras sequences in papillomavirus-associated carcinomas of the upper alimentary canal of cattle was investigated by restriction enzyme and hybridization analysis, and by DNA-mediated transformation of NIH3T3 cells. In three cancers, a squamous cell carcinoma of the palate, a squamous cell carcinoma of the rumen, and a transitional cell carcinoma of the urinary bladder, repetitive DNA sequences present in the Ha-ras 1 locus showed anomalous restriction patterns, indicating rearrangements and, in the case of the palate cancer, amplification. Genomic DNA from several cancers was capable of inducing focus formation in the NIH3T3 transformation test. DNA from primary, secondary and tertiary transformants was analysed by hybridization to bovine ras probes and by nucleotide sequencing of polymerase chain reaction products. Bovine Ha-ras 1 sequences were found in all transformants, but no nucleotide differences were detected in exon 1 or exon 2 between normal, cancer and transformed cells. It is concluded that the Ha-ras 1 gene is activated in alimentary canal carcinomas, although the activating mutation has not yet been mapped. The possible relationship between papillomavirus infection and activation of the ras gene is considered.     

Detection and identification of activated oncogenes in human skin cancers occurring on sun-exposed body sites

High-molecular-weight DNA isolated from eight fresh human skin cancers occurring on sun-exposed body sites were assayed for their ability to transform NIH 3T3 cells. A cotransfection protocol using pSV2-neo DNA, which confers resistance to the antibiotic G418, was used to select cells that had taken up the transfected DNA. About 2 weeks after transfection, G418-resistant colonies were pooled and injected s.c. into athymic nude mice. The NIH 3T3 cells transfected with DNA from six of the human skin cancers induced tumors in nude mice. DNAs from all six tumor cell lines contained human alu sequences. Southern blot hybridization with ras-specific probes revealed that DNAs from the four alu-rich tumors contained the human Ha-ras oncogene, in addition to that of the NIH 3T3 controls. In contrast, DNAs from the other two tumors did not contain any of the known oncogenes tested, except those endogenous to NIH 3T3 cells. DNAs from three of four first cycle tumorigenic transformants gave rise to morphologically transformed foci when assayed in a second cycle of transfection. DNAs from all three secondary transformants contained discrete human alu sequences, and in addition, contained Ha-ras sequences similar to those present in their respective primary transformants. Interestingly, DNA from both primary and secondary transformants of one particular human squamous cell carcinoma contained highly amplified copies of the Ha-ras oncogene. These results suggest that activation of the Ha-ras oncogene may be common in human skin cancers originating on sun-exposed body sites. Further characterization of the Ha-ras oncogenes present in these human skin cancers may provide information on the molecular mechanisms by which UV radiation of the sun induces human neoplasms on exposed body sites.     

Activation of K-ras and oncogenes other than ras family in rat fibrosarcomas induced by 1,8-dinitropyrene

Oncogenes of fibrosarcomas of rats, induced by subcutaneous injection of 1,8-dinitropyrene (1,8-DNP), were examined by NIH 3T3 cell transfection assay and Southern blot analysis. Transformants containing rat specific repetitive sequences were obtained with DNAs of 4 fibrosarcomas, 1,8-DNP1, 1,8-DNP2, 1,8-DNP3 and 1,8-DNP7. A transformant, 1,8-DNP2-2, induced by DNA of a fibrosarcoma, 1,8-DNP2, and 7 secondary transformants derived from it contained rat K-ras sequences. Another transformant, 1,8-DNP2-1, induced by the same sarcoma did not have a ras family oncogene. This indicates that the sarcoma, 1,8-DNP2, has at least 2 transforming genes. The transforming genes of 6 other transformants derived from 3 sarcomas did not contain ras family or neu transforming genes.     

Human oncogenes detected by a defined medium culture assay

Oncogenes in DNAs from human tumor cell lines have been detected by a new transformation assay. Cellular DNAs are transfected into NIH3T3 murine fibroblasts, and transformed cells are selected by maintaining cell cultures in a defined medium lacking platelet-derived or fibroblast growth factors. DNAs from eight of 17 human tumor cell lines have yielded transformants by this method. Activated cellular ras genes account for three of the transforming activities. The SAOS2 osteosarcoma cell line contains an activated oncogene distinct from 18 known oncogenes. Another cellular oncogene was detected as the consequence of a fortuitous transfection-mediated DNA rearrangement.     

Detection of distinct transforming genes in X-ray induced tumors

DNAs from mouse skin tumors (papillomas, squamous cell carcinomas,basal cell carcinomas and pilomatrixomas) initiated with X-irradiationand promoted with 12-O-tetradecanoyl-phorbol-13-acetate (TPA)demonstrated dominant transforming activity by the productionof transformed foci in the mouse recipient tine, NIH3T3. Dominanttransforming activity was not found in DNA isolated from normalmouse epidermis or from the corresponding liver. The NIH3T3transformants induced with squamous cell carcinoma DNA grewin soft agar and formed tumors in nude mice. Southern blot analysisof primary NIH3T3 transformant DNAs carrying oncogenes fromradiation-initiated squamous cell carcinomas indicated thatthe oncogenes responsible for the transformation of the recipientcells were not Ha-ras, Ki-ras or N-ras genes, nor were theyerbB, B-lym, met, neu or raf. The data presented indicate thatDNAs from radiation-initiated mouse skin tumors contain dominanttransforming genes that are detectable by DNA-mediated genetransfer. The oncogene sequences activated in these radiation-initiatedtumors are distinct non-ras transforming genes.     

Activated Ki-ras genes in bladder epithelial cell lines transformed by treatment of primary mouse bladder explant cultures with 7,12-dimethylbenz[a]anthracene

DNA from five lines of transformed bladder epithelial cells derived from cultures of primary cells that had been treated with 7,12-dimethylbenz[a]anthracene (DMBA) can transform NIH 3T3 mouse fibroblasts in DNA transfection experiments. Southern analysis of DNA from NIH 3T3 primary and secondary transformants established that four of the DMBA-transformed cell lines contained activated cellular Ki-ras, while the remaining cell line contained a transforming gene that is unrelated to Ki-ras, N-ras, and Ha-ras. The point mutations responsible for Ki-ras activation were detected using oligonucleotide probes following selective amplification of Ki-ras specific sequences using the polymerase chain reaction. The results showed that activation of Ki-ras invariably involved a GC----AT transition mutation of the first position of codon 12. Surprisingly, a Ki-ras gene that was activated by a GC----AT transition mutation at the same position was also detected in a single transformed bladder urothelial cell line derived from control cultures of mouse bladder cells. Together, our results indicate that Ki-ras activation in the DMBA-transformed bladder cell lines may not be a direct consequence of interaction of activated DMBA metabolites with the Ki-ras gene.     

DNA transformation activity of a human gastrocarcinoma cell line

DNAs of three cell lines of human gastrocarcinoma (MGC-803, BGC-823 and PACM-82) and two fresh solid tumors of human stomach cancer were used to transfect NIH3T3 and Rat-1 cells. The transformed cells were selected with high concentration of glucose and low concentration of serum, or with medium containing Geneticin (G418) after co-transfection of pSVneo and DNAs of stomach cancer cell line or primary transformants. From the second round transfection, we had obtained transformants which could grow with high colony forming efficiency in soft agarose and were tumorigenic in nude mice. The southern blot analysis showed that the cellular DNA of the transformants contained human Alu repeat sequence and the transformed gene from stomach cancer cell line (BGC-823) and was homologous to proto-oncogene c-Ha-ras. The transforming gene is able to induce neoplastic transformation of NIH3T3 and Rat-1 cells.     

ras oncogenes and phenotypic staging in N-methylnitrosourea- and gamma-irradiation-induced thymic lymphomas in C57BL/6J mice

We have investigated stages of thymic lymphoma development in radiation and N-methylnitrosourea (NMU)-treated C57BL/6J mice. The lymphoma cell was identified serologically as a cortical population bearing MEL-14hi, H-2Khi, and IL-2R+ surface markers. According to these parameters in C57BL/6J mice the lymphoma cell was the same regardless of inducing agent or activated oncogene (ras or non-ras). Transforming activity in the radiation and NMU-induced tumors was analyzed using both the nude mouse tumorigenicity assay and the focus-forming assay. 8/10 NMU-induced tumors and 12/15 radiation-induced tumors showed transforming activity in the tumorigenicity assay. Southern blot analysis of the nude mouse transformants demonstrated K-ras transforming sequences in eight of eight NMU-induced lymphoma DNAs, two of 12 radiation-induced lymphoma DNAs and N-ras transforming sequences in five of 12 radiation-induced lymphoma DNAs. The non-ras transforming activity in five DNAs from radiation-induced thymic lymphomas indicates the presence of an unidentified oncogene(s) in these tumors. Staging of thymic lymphoma development in this animal model system will allow the study of oncogene activation early in the course of carcinogen-induced disease. These results also emphasize the high sensitivity of the nude mouse assay to score for activated oncogenes and might also indicate a high frequency of K-ras activation in NMU-induced lymphomas in C57BL/6J mice.     

Expression of LY-6.2 and Thy-1 antigens on NIH 3T3 cells suppressed after transformation with activated human ras-oncogenes

We have studied the expression of several cell surface antigens in NIH 3T3 cells after neoplastic transformation with activated human ras and myc oncogenes. The binding of monoclonal antibodies (MAbs), specific for mouse differentiation antigens Ly-6.2, Thy-1 and 9F3, to normal and transformed cells was assessed using a fluorescence-activated cell sorter (FACS IV). Significant reduction of Ly-6.2 and Thy-1 antigen expression was detected in cells transformed with either the N-ras, Ki-ras or H-ras oncogenes but not in c-myc transfected cells. 9F3 antigen expression remained at the original high level in all transfectants studied. Normal levels of Ly-6.2 and Thy-1 expression reappeared in revertants derived from: unstable ras-transfectants. These data indicate that ras sequences did not preferentially transform cells that were deficient in Ly-6.2 and Thy-l antigens. It was also shown that the reduced binding of anti-Ly-6.2 antibodies to ras-transfectants was not due to a masking effect of increased cell-surface sialylation occurring in ras-transfected cell lines. Other possible explanations of the detected phenotypic changes are discussed. The results extend the range of tumor-associated membrane alterations in NIH 3T3 cells following transfection with human tumor DNA containing activated ras oncogenes by a hitherto unreported alteration in the expression of Ly-6 and Thy-1 antigens.     

Syrian hamster embryo cell lines useful for detecting transforming genes in mouse tumours: detection of transforming genes in X-ray-related mouse tumours.

The Syrian hamster embryo cell lines, SHOK and MC-1, were used as recipient cells for DNA transfection assay to detect transforming genes in experimental mouse tumours. A mouse repeat sequence was utilised to check whether each transformed focus included mouse genomic DNA in the Hamster background. We investigated five mouse tumours that are related to X-ray radiation, and detected activated c-K-ras, c-mos, and c-cot oncogenes which induced foci of hamster cells. These results show that SHOK and MC-1 cells have unique properties for detecting transforming genes in experimental mouse tumours.     

Activating point mutation in Ki-ras codon 63 in a chemically induced rat renal tumor.

Renal mesenchymal tumors induced in F344 rats with methyl(methoxymethyl)nitrosamine (DMN-OMe) have previously been shown by our laboratory to contain transforming Ki-ras sequences, activated most commonly by a variety of codon 12 mutations. Further sequence analysis of the one DMN-OMe-induced tumor with transforming Ki-ras sequences detected by NIH 3T3 transfection assay but with no mutation in codon 12 detected by selective oligonucleotide hybridization has now revealed an activating point mutation in codon 63. The observed GAG----AAG transition in codon 63, which replaces glutamic acid with lysine, was the only detectable mutation in exon 1 and 2 hotspot regions of Ki-ras in this tumor. The same mutation was also detected in Ki-ras sequences derived from first- and second-cycle transformants in NIH 3T3 transfection assays. Although random mutagenesis studies of cloned Ha-ras sequences by Fasano et al. (Proc Natl Acad Sci USA 81:4008-4012, 1984) had already indicated that GAG----AAG mutations in codon 63 of ras are transforming, this is the first demonstration of the natural occurrence of this particular activating mutation in a tumor.     

Activated oncogenes in a rat hepatocellular carcinoma induced by 2-amino-3-methylimidazo[4,5-f]quinoline

The presence of activated oncogenes in several rat hepatocellular carcinomas induced by 2-amino-3-methylimidazo[4,5-f]-quinoline (IQ) was examined by NIH 3T3 cell transfection assay and Southern blot analysis. In one tumor, IQ4, rat H-ras-1 and another oncogene that did not belong to the ras family were found to be activated.     

Isolation of activated ras transforming genes from two patients with Hodgkin's disease

Despite impressive advances in the clinical management of Hodgkin's disease, little is known about its cellular origin or the mechanism(s) of "Hodgkinogenesis." Recent findings that certain human cellular oncogenes can cause malignant transformation suggest that aberrant activation of these genes may play a role in carcinogenesis. To determine if such genes are operative in Hodgkin's cells, we isolated DNA from splenic nodules of three patients with nodular sclerosis Hodgkin's disease and tested its ability to transform mouse NIH 3T3 cells, the standard assay for oncogene-mediated malignant transformation. Transformed cells containing human DNA were obtained from two patients. DNA from these primary transformants yielded secondary transformants of NIH 3T3 fibroblasts; one also transformed normal mouse bone marrow macrophages, a cell type probably related to the Hodgkin's cell. When analyzed by Southern blot methods for homology with closed oncogene probes, the transforming genes from both patients had homology with N-ras. The homology and size of the restriction fragments were similar to those of transforming genes isolated from patients with acute nonlymphocytic leukemias. The presence of the same activated oncogene in tumor tissue from two different patients suggests that it may play an important role in Hodgkinogenesis.