Characterization of c-Ki-ras and N-ras oncogenes in aflatoxin B1-induced rat liver tumors.

c-Ki-ras and N-ras oncogenes have been characterized in aflatoxin B1-induced hepatocellular carcinomas. Detection of different protooncogene and oncogene sequences and estimation of their frequency distribution were accomplished by polymerase chain reaction, cloning, and plaque screening methods. Two c-Ki-ras oncogene sequences were identified in DNA from liver tumors that contained nucleotide changes absent in DNA from livers of untreated control rats. Sequence changes involving G.C to T.A or G.C to A.T nucleotide substitutions in codon 12 were scored in three of eight tumor-bearing animals. Distributions of c-Ki-ras sequences in tumors and normal liver DNA indicated that the observed nucleotide changes were consistent with those expected to result from direct mutagenesis of the germ-line protooncogene by aflatoxin B1. N-ras oncogene sequences were identified in DNA from two of eight tumors. Three N-ras gene regions were identified, one of which was shown to be associated with an oncogene containing a putative activating amino acid residing at codon 13. All three N-ras sequences, including the region detected in N-ras oncogenes, were present at similar frequencies in DNA samples from control livers as well as liver tumors. The presence of a potential germ-line oncogene may be related to the sensitivity of the Fischer rat strain to liver carcinogenesis by aflatoxin B1 and other chemical carcinogens.     

Human genome contains four genes homologous to transforming genes of Harvey and Kirsten murine sarcoma viruses.

Harvey and Kirsten murine sarcoma viruses each encode a structurally and functionally related 21-kilodalton protein (p21), which is the transforming protein of each virus. Using probes from the 0.9-kilobase (kb) p21-coding region of each virus (called v-Ha-ras and v-Ki-ras, respectively), we have molecularly cloned from normal human genomic DNA the sequences that hybridize to these probes. Four evolutionarily divergent restriction endonuclease fragments were isolated. Two hybridized preferentially to v-Ha-ras and were designated human c-Ha-ras1 and c-Ha-ras2; two hybridized preferentially to v-Ki-ras and were called c-Ki-ras1 and c-Ki-ras2. Human c-Ha-ras1 contained 0.9 kb of sequence homologous with v-Ha-ras interspersed with three intervening sequences; this gene was closely related to a previously cloned rat c-Ha-ras gene that also contained intervening sequences. Human c-Ha-ras2 was more divergent from v-Ha-ras and also hybridized poorly to human c-Ha-ras1. One c-Ki-ras gene contained 0.9 kb homologous to v-Ki-ras and had one intervening sequence, whereas the other contained only 0.3 kb homologous to v-Ki-ras. The results indicated that human DNA contains several copies of the c-ras family and that c-Ha-ras1 (with intervening sequences) was more highly conserved evolutionarily than was c-Ha-ras2.     

Activated neu oncogene sequences in primary tumors of the peripheral nervous system induced in rats by transplacental exposure to ethylnitrosourea.

Neurogenic tumors were selectively induced in high incidence in F344 rats by a single transplacental exposure to the direct-acting alkylating agent N-ethyl-N-nitrosourea (EtNU). We prepared DNA for transfection of NIH 3T3 cells from primary glial tumors of the brain and from schwannomas of the cranial and spinal nerves that developed in the transplacentally exposed offspring between 20 and 40 weeks after birth. DNA preparations from 6 of 13 schwannomas, but not from normal liver, kidney, or intestine of tumor-bearing rats, transformed NIH 3T3 cells. NIH 3T3 clones transformed by schwannoma DNA contained rat repetitive DNA sequences, and all isolates contained rat neu oncogene sequences. One schwannoma yielded a transformant with rat-specific sequences for both neu and N-ras. A point mutation in the transmembrane region of the putative protein product of neu was identified in all six transformants and in the primary tumors from which they were derived as well as in 5 of 6 schwannomas tested that did not transform NIH 3T3 cells. Of 59 gliomas, only one yielded transforming DNA, and an activated N-ras oncogene was identified. The normal cellular neu sequence for the transmembrane region, but not the mutated sequence, was identified in DNA from all 11 gliomas surveyed by oligonucleotide hybridization. Activation of the neu oncogene, originally identified [Schechter, A.L., Stern, D.F., Vaidyanathan, L., Decker, S.J., Drebin, J.A., Greene, M.I. & Weinberg, R.A. (1984) Nature (London) 312, 513-516] in cultured cell lines derived from EtNU-induced neurogenic tumors that by biochemical but not histologic criteria were thought to originate in the central nervous system in BD-IX rats, appears specifically associated with tumors of the peripheral nervous system in the F344 inbred strain.     

Activation of ras oncogene in aflatoxin-induced rat liver carcinogenesis.

The presence of activated transforming genes was investigated in four primary aflatoxin-induced rat liver tumors in male Fischer rats, in two cell lines generated from such tumors, in an epithelial liver-derived nontransformed cell line, and in the latter cell line after transformation by aflatoxin B1 in vitro. When DNA extracted from these sources was transfected into NIH 3T3 cells, negative results were obtained from focus assays. Cotransfection of these DNA samples with a gene for resistance to G418, followed by selection for resistance to that antibiotic, and tumorigenicity testing in nude mice demonstrated DNA-mediated transfer of the neoplastic phenotype in all cases except for DNA from the nontransformed cell line. DNA extracted from these primary nude mouse tumors used in a secondary round of transfection with NIH 3T3 cells gave positive results in focus assays, which were conserved through succeeding rounds of transfection. By use of appropriate radiolabeled probes, activated ras oncogenes were detected in all samples. N-ras activation was detected in three of the primary rat liver tumors and both hepatoma cell lines. Ki-ras activation was detected in one primary rat liver tumor, and Ha-ras activation was detected in the cell line transformed in vitro with activated aflatoxin B1. The activated Ki-ras oncogene was further characterized by use of synthetic oligonucleotide probes and was shown to contain a G----A transition at the second nucleotide in codon 12.     

Characterization of c-Ki-ras oncogene alleles by direct sequencing of enzymatically amplified DNA from carcinogen-induced tumors.

Activated c-Ki-ras genes in liver tumors from rats exposed to the potent hepatocarcinogen aflatoxin B1 were analyzed to determine the nature of their activation by characterization of two c-Ki-ras alleles present in tumor-derived NIH 3T3 mouse transformants. Using selective hybridization of synthetic oligonucleotides to transformant DNA, we have determined that a single G X C to A X T base transition in either the first or second position of the 12th codon is associated with activation of the gene. Such mutations would lead to amino acid substitutions of aspartate or serine for glycine in the mutant proteins. To confirm these findings, we applied a technique for direct sequence analysis of a 90-base-pair region of the rat c-Ki-ras gene produced by primer-directed enzymatic amplification. Findings produced by this approach, which provides a convenient method to characterize mutations in multiple alleles without the necessity to clone individual genes, confirmed the presence and identity of the 12th codon mutations in the activated oncogene, as initially determined by the oligonucleotide hybridization technique.     

Activating mutations of the c-Ha-ras protooncogene in chemically induced hepatomas of the male B6C3 F1 mouse.

Activated c-Ha-ras protooncogenes have recently been identified in the DNA of some spontaneous hepatic tumors found in 2-year-old B6C3 F1 mice. Activation of c-Ha-ras has now been demonstrated in DNA from well-differentiated hepatomas initiated by a single dose of carcinogen given to male B6C3 F1 mice at 12 days of age. DNA from each of 25 hepatomas, induced by N-hydroxy-2-acetylaminofluorene, vinyl carbamate, or 1'-hydroxy-2',3'-dehydroestragole, containing transforming activity in the NIH 3T3 transfection assay. Southern analysis of NIH 3T3 cells transformed by DNA from 24 of these hepatomas revealed amplified and/or rear-ranged restriction fragments homologous to a Ha-ras probe. The other tumor contained an activated Ki-ras gene. Immunoprecipitation and NaDodSO4/PAGE analysis of p21 ras proteins in NIH 3T3 transformants derived from a majority of the hepatomas suggested that the activating mutations were localized in the 61st codon of the c-Ha-ras gene. Creation of a new Xba I restriction site by an AT----TA transversion at the second position of codon 61 was detected in DNA from primary tumors and NIH 3T3 cells transformed by DNA from 6 of 7 vinyl carbamate- and 5 of 10 1'-hydroxy-2',3'-dehydroestragole-induced hepatomas. Selective oligonucleotide hybridization demonstrated a CG----AT transversion at the first position of the 61st codon in NIH 3T3 transformants derived from 7 of 7 N-hydroxy-2-acetylaminofluorene-induced hepatomas. By the same criterion, an AT----GC transition at the second position of codon 61 was the activating mutation in 1 of 7 vinyl carbamate- and 5 of 10 1'-hydroxy-2',3'-dehydroestragole-induced tumors. Thus, c-Ha-ras activation is apparently an early event in B6C3 F1 mouse hepatocarcinogenesis that results directly from reaction of ultimate chemical carcinogens with this gene in vivo.     

Mutations in c-Ki-ras oncogenes in diseased livers of winter flounder from Boston Harbor.

Livers of a natural population of winter flounder from a contaminated site in Boston Harbor were examined for the presence of oncogenes by transfection of DNA into NIH 3T3 mouse fibroblasts. Tissues analyzed contained histopathologic lesions including abnormal vacuolation, biliary proliferation, and, in many cases, hepatocellular and cholangiocellular carcinomas. Fibroblasts transfected with liver DNA samples from 7 of 13 diseased animals were effective in the induction of subcutaneous sarcomas in nude mice. Further analysis revealed the presence of flounder c-Ki-ras oncogenes in all 10 nude mouse subcutaneous tumors analyzed. Direct DNA sequencing and allele-specific oligonucleotide hybridization following amplification of the tumor DNA by the polymerase chain reaction showed mutations in the 12th codon in this gene. Analysis of DNA from all nude mouse tumors as well as the livers from which they were derived showed mutations at this codon. The mutations comprised G.C----A.T or G.C----T.A base changes resulting in substitution of serine, valine, or cysteine for glycine. Liver DNA samples from five histologically normal livers of animals from a less polluted site were ineffective in the transfection assay and showed only wild-type DNA sequences (GGT) at the 12th codon of c-Ki-ras. The prevalence of mutations in this gene region was associated with the presence of liver lesions and could signify DNA damage resulting from environmental chemical exposure.     

Ovarian expression of cellular Ki-ras p21 varies with physiological status.

To elucidate the potential role of the ras protooncogene proteins in a specific tissue, the present study determined the levels of individual c-ras-encoded p21 proteins in the rat ovary during various stages of physiological function. p21 protein was extracted from ovaries taken from immature normal female rats, mature nonpregnant animals in the metestrus stage of the estrus cycle, rats at various stages of pregnancy, and actively lactating animals. Levels of individual p21s were evaluated by immunoblot analysis with specific antibodies to the p21 proteins encoded by the Kirsten, Harvey, and neuroblastoma c-ras protooncogenes, c-Ki-ras, c-Ha-ras, and N-ras. Results showed that c-Ki-ras p21 is at its lowest level in the immature ovary and increases with development of the corpora lutea to its highest levels at day 16 of pregnancy, after which levels decline and then rise again during lactation. This pattern, which mimics that of circulating progesterone levels, suggests that ovarian c-Ki-ras p21 levels are regulated and that c-Ki-ras p21 plays a role in the differentiated function of the rat ovary, likely the luteal compartment. In contrast, levels of c-N-ras p21 did not appear to vary with changes in the physiological function of the ovary but appeared to be constitutive. A preferential role for the c-Ki-ras p21 may be due to the documented unique differences in the structure of the carboxyl terminus of this particular c-ras p21.     

Identification and expression of human c-Ha-ras and c-sis sequences in NIH3T3 transformants

High-molecular-weight DNAs from 5 bladder carcinomas were used in transfection of mouse NIH3T3 cells. The manifestation of heterologous oncogene(s) expression in NIH3T3 cells was morphological transformation very often accompanied by changes in growth characteristics of recipient cells. In DNA samples from secondary NIH3T3 transformants human c-Ha-ras and c-sis sequences were identified. In some secondary transformants these sequences were expressed. On the basis of change of the growth characteristics of some secondary transformants we could expect the integration and expression of another human gene(s) for growth factor or growth factor receptor or even activation of mouse genes. We did not manage to identify any Alu sequences in some secondary transformants carrying human c-Ha-ras sequences. On the other hand, it has not been revealed yet that BamHI DNA fragments carrying c-Ha-ras gene contained any Alu sequence. So, the identification of Alu sequences does not have to be the first step in investigation of DNA samples from NIH3T3 transformants.     

Hamster cell line suitable for transfection assay of transforming genes.

We established a subclone, SHOK, from the GHE-L cell line, an immortal line derived from a primary culture of Syrian hamster embryo cells, as a recipient cell line useful for the detection of oncogenes by transfection. SHOK cells were almost as susceptible as NIH 3T3 cells to focus formation by many oncogenes, including v-raf, v-Ha-ras, v-Ki-ras, or activated c-Ha-ras. The susceptibility of SHOK to focus formation was higher than that of NIH 3T3 for v-mos but was lower for v-fps, v-fgr, v-src, v-sis, and v-abl. When DNAs extracted from 27 human and murine tumors were tested for focus formation, 5 DNAs were positive in NIH 3T3 cells, whereas 9 were positive in SHOK cells at the primary transfection. Using SHOK cells as recipients of tumor cellular DNA, we isolated another oncogene and a c-Ki-ras2 gene mutated at codon 146 that were difficult to detect in NIH 3T3 cells. SHOK cells have a low rate of spontaneous transformation, produce easily distinguishable foci, and maintain a stable karyotype in transformed cells. In addition to being useful for the screening of human tumor DNAs, SHOK cells will be useful for the isolation of oncogenes from murine tumors because of their hamster origin.     

Activation of related transforming genes in mouse and human mammary carcinomas.

High molecular weight DNAs of five tumors induced by mouse mammary tumor virus (MMTV), two mouse mammary tumors induced by a chemical carcinogen, and one human mammary tumor cell line (MCF-7) were assayed for the presence of transmissible activated transforming genes by transfection of NIH 3T3 mouse cells. DNAs of all five MMTV-induced tumors, one chemical carcinogen-induced tumor, and the human tumor cell line induced transformation with high efficiencies (approximately 0.2 transformant per micrograms of DNA). NIH cells transformed by DNAs of MMTV-induced tumors did not contain exogenous MMTV DNA sequences, indicating that MMTV-induced mammary carcinomas contained activated cellular transforming genes that were not linked to viral DNA. The transforming activities of DNAs of all five MMTV-induced tumors, the chemical carcinogen-induced mouse tumor, and the human tumor cell line were inactivated by digestion with the restriction endonucleases Pvu II and Sac I, but not by BamHI, EcoRI, HindIII, Kpn I, or Xho I. These results indicate that the same or closely related transforming genes were activated in six different mouse mammary carcinomas, induced by either MMTV or a chemical carcinogen, and in a human mammary carcinoma cell line.     

Identification by transfection of transforming sequences in DNA of human T-cell leukemias.

DNA from human T-cell leukemia cell lines was tested for focus-inducing activity on cultures of NIH 3T3 cells. Three leukemias yielded DNA active in this assay; restriction enzyme sensitivity of this activity indicated that similar, relatively large DNA sequences were involved. Southern blot analysis revealed conserved size classes of restriction fragments containing human repetitive (Alu) sequences in serially transfected foci derived from the active DNAs. Similar blot hybridizations with a probe specific for the human N-ras oncogene detected a 9-kilobase EcoRI fragment in all cases. DNA containing this fragment from one of the leukemias, molecularly cloned in bacteriophage lambda, displayed highly amplified focus-inducing activity in transfection assays. Thus, the N-ras oncogene appears to be active in these three human leukemias of T-cell origin.     

Isolation of transforming sequences of two human lung carcinomas: structural and functional analysis of the activated c-K-ras oncogenes.

Human lung tumors PR310 and PR371 maintained in nude mice contain activated c-K-ras oncogenes detectable by the ability of their DNAs to induce the morphological transformation of NIH 3T3 mouse fibroblasts. Using phage libraries constructed with DNA from NIH 3T3 mouse fibroblast transformants, we have isolated human sequences that span greater than 40 kilobase pairs of the c-K-ras oncogene. Based on the conservation of these human sequences in mouse fibroblast transformants, we conclude that the transforming ability of the oncogene activated in these tumors resides within a 43- to 46-kilobase-pair DNA region. No clear differences were observed between the structures of the PR310 and PR371 cloned oncogene sequences. Nucleotide sequence analysis in concert with DNA transfection experiments suggests that the PR371 oncogene has been activated by a single base change in the first exon, which results in the substitution of cysteine for glycine in position 12 of the predicted amino acid sequence. The genetic alteration responsible for the transforming activity of the PR310 oncogene, however, does not reside in the first exon. These results indicate that the activation of the c-K-ras oncogene in human lung cancer can occur by different mutational events.     

Chromosome assignments of four mouse cellular homologs of sarcoma and leukemia virus oncogenes.

Molecular probes for the oncogenes of Rous sarcoma virus (v-src), avian myeloblastosis virus (v-myb), Kirsten murine sarcoma virus (v-Ki-ras), and Harvey murine sarcoma virus (v-Ha-ras) were hybridized to the DNA from mouse-Chinese hamster somatic cell hybrids. The v-src, v-myb, v-Ki-ras, and v-Ha-ras genes each detected one or a few homologous mouse DNA fragments whose segregation was analyzed in cell hybrids. Mouse cellular homologs c-src, c-Ki-ras, c-Ha-ras, and c-myb segregated concordantly with chromosomes 2, 6, 7, and 10, respectively. Comparison with the known locations of human c-src (chromosome 20) and human c-Ha-ras1 (chromosome 11 short arm) suggests that the human and mouse homologs of these two viral oncogenes reside in conserved linkage groups. The c-Ki-ras gene on mouse chromosome 6 might reside also in a conserved linkage group, along with glyceraldehyde-3-phosphate dehydrogenase and triosephosphate isomerase. However, direct confirmation of this suggestion must await a demonstration that c-Ki-ras on mouse chromosome 6 is homologous to c-Ki-ras2 on the short arm of human chromosome 12.     

High frequency of N-ras activation in acute myelogenous leukemia

Using the NIH/3T3 cell transfection assay, activated cellular oncogenes have been detected in around 10% to 20% of human tumors. From a series of DNA preparations from tissues infiltrated with acute myelogenous leukemia (AML), 50% (3/6) caused transformation of NIH/3T3 cells. Thus AML appears to be the human tumor with the highest frequency of oncogenes detected by DNA transfection. In each case the oncogene involved was N-ras, a member of the ras gene family. Biologic and clinical parameters of AML patients with and without N-ras oncogenes in their tumors are discussed.     

Detection and identification of activated oncogenes in spontaneously occurring benign and malignant hepatocellular tumors of the B6C3F1 mouse

Species- and strain-specific spontaneously occurring tumors have been observed in rodents maintained under normal laboratory conditions. Elucidation of the molecular mechanisms associated with the development of these spontaneous tumors may provide a better understanding of tumor development associated with exposure to chemical carcinogens. In view of the high frequencies of oncogene activation shown in rodent tumors induced by known chemical carcinogens, we have investigated oncogene activation in spontaneous tumors of the B6C3F1 mouse and Fischer 344/N rat by DNA transfection techniques. A marked difference in the presence of activated oncogenes in spontaneous rat tumors versus spontaneous mouse liver tumors was observed in this study. All rat tumors tested failed to yield activated oncogenes (0/29), whereas 30% (3/10) of mouse hepatocellular adenomas and 77% (10/13) of hepatocellular carcinomas scored positive by DNA transfection. These transforming genes were identified as an activated Ha-ras gene in all the adenoma transfectants and in 8 of the 10 carcinoma transfectants. The two remaining hepatocellular carcinomas contained transforming genes that appear not to be members of the known ras gene family. The B6C3F1 mouse liver system might provide a very sensitive assay not only for assessing the potential of a chemical to activate a cellular proto-oncogene, but also for detecting various classes of proto-oncogenes that are susceptible to mutational activation.     

Transforming genes in human leukemia cells

High-molecular weight DNAs of fresh bone marrow cells from 32 patients with fresh leukemia were assayed for the presence of transmissible activated transforming genes by a DNA-mediated gene transfer technique using NIH/3T3 cells. DNAs of bone marrow cells from four of the 32 patients induced transformation of NIH/3T3 cells. Two of the four cases, a chronic myelogenous leukemia and an acute lymphocytic leukemia, contained activated N-ras oncogenes. Molecular cloning and nucleotide sequence analysis revealed that the lesion responsible for the transforming activity was localized to a single nucleotide transition from guanine to thymine in codon 12 of the predicted protein in each of the two cases. These observations indicate that activation of N-ras oncogenes is independent of the specific stage of cell differentiation or the leukemia phenotype. The other two transforming genes associated with an acute myelogenous leukemia and an acute lymphocytic leukemia showed homology neither with members of the ras gene family nor with the human Blym-1 gene. Thus, the NIH/3T3 transfection assay frequently detects activated N-ras oncogenes in human leukemias, while other transforming genes, distinct from the ras gene family, can be detected in some leukemias by the transfection assay.     

Transforming gene in human atherosclerotic plaque DNA.

The monoclonal hypothesis equates atherosclerotic plaques with benign smooth muscle cell tumors and proposes that plaques can arise via mutational or viral events. Here, we provide direct evidence that molecular events, heretofore associated only with tumor cells, are common to plaque cells as well. Three distinct groups of human coronary artery plaque (hCAP) DNA samples transfected into NIH 3T3 cells gave rise to transformed foci. DNA samples from a panel of normal noncancerous human tissues, including coronary artery, were negative in the assay. Southern-blotted focus DNA yielded positive signals when hybridized to the 32P-labeled nick-translated repetitive human "Alu" DNA sequence. The DNA from cloned foci was used successfully in a second round of transfection. Focus DNA hybridized to nick-translated v-Ki-ras, v-Ha-ras, or N-ras probes failed to detect human fragments of these genes. Primary focus cells from each of five clones elicited tumors after injection into nude mice (6/42). Several distinct high molecular weight (greater than 6.6 kilobases) bands were detected after BamHI-digested tumor DNA was hybridized to Alu. Preliminary characterization of these hCAP DNA-associated tumors indicates that they are similar to the fibrosarcomas that arise after injection of ras-transformed cells into nude mice. We propose that transforming genes in plaque cells behave in a manner analogous to the way in which oncogenes behave in cancer cells.