Relating aromatic hydrocarbon-induced DNA adducts and c-H-ras mutations in mouse skin papillomas: the role of apurinic sites.

Mouse skin tumors contain activated c-H-ras oncogenes, often caused by point mutations at codons 12 and 13 in exon 1 and codons 59 and 61 in exon 2. Mutagenesis by the noncoding apurinic sites can produce G-->T and A-->T transversions by DNA misreplication with more frequent insertion of deoxyadenosine opposite the apurinic site. Papillomas were induced in mouse skin by several aromatic hydrocarbons, and mutations in the c-H-ras gene were determined to elucidate the relationship among DNA adducts, apurinic sites, and ras oncogene mutations. Dibenzo[a,l]pyrene (DB[a,l]P), DB[a,l]P-11,12-dihydrodiol, anti-DB[a,l]P-11,12-diol-13,14-epoxide, DB[a,l]P-8,9-dihydrodiol, 7,12-dimethylbenz[a]anthracene (DMBA), and 1,2,3,4-tetrahydro-DMBA consistently induced a CAA-->CTA mutation in codon 61 of the c-H-ras oncogene. Benzo[a]pyrene induced a GGC-->GTC mutation in codon 13 in 54% of tumors and a CAA-->CTA mutation in codon 61 in 15%. The pattern of mutations induced by each hydrocarbon correlated with its profile of DNA adducts. For example, both DB[a,l]P and DMBA primarily form DNA adducts at the N-3 and/or N-7 of deoxyadenosine that are lost from the DNA by depurination, generating apurinic sites. Thus, these results support the hypothesis that misreplication of unrepaired apurinic sites generated by loss of hydrocarbon-DNA adducts is responsible for transforming mutations leading to papillomas in mouse skin.     

Carcinogen-induced mutations in the mouse c-Ha-ras gene provide evidence of multiple pathways for tumor progression.

A number of mouse skin tumors initiated by the carcinogens N-methyl-N'-nitro-N-nitrosoguanidine (MNNG), methylnitrosourea (MNU), 3-methylcholanthrene (MCA), and 7,12-dimethylbenz[a]anthracene (DMBA) have been shown to contain activated Ha-ras genes. In each case, the point mutations responsible for activation have been characterized. Results presented demonstrate the carcinogen-specific nature of these ras mutations. For each initiating agent, a distinct spectrum of mutations is observed. Most importantly, the distribution of ras gene mutations is found to differ between benign papillomas and carcinomas, suggesting that molecular events occurring at the time of initiation influence the probability with which papillomas progress to malignancy. This study provides molecular evidence in support of the existence of subsets of papillomas with differing progression frequencies. Thus, the alkylating agents MNNG and MNU induced exclusively G ---- A transitions at codon 12, with this mutation being found predominantly in papillomas. MCA initiation produced both codon 13 G ---- T and codon 61 A ---- T transversions in papillomas; only the G ---- T mutation, however, was found in carcinomas. These findings provide strong evidence that the mutational activation of Ha-ras occurs as a result of the initiation process and that the nature of the initiating event can affect the probability of progression to malignancy.     

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.     

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.     

Characterization of mutagen-activated cellular oncogenes that confer anchorage independence to human fibroblasts and tumorigenicity to NIH 3T3 cells: sequence analysis of an enzymatically amplified mutant HRAS allele.

Treatment of diploid human fibroblasts with an alkylating mutagen has been shown to induce stable, anchorage-independent cell populations at frequencies (11 X 10(-4) consistent with an activating mutation. After treatment of human foreskin fibroblasts with the mutagen benzo[a]pyrene (+/-)anti- 7,8-dihydrodiol 9,10-epoxide and selection in soft agar, 17 anchorage-independent clones were isolated and expanded, and their cellular DNA was used to cotransfect NIH 3T3 cells along with pSV2neo. DNA from 11 of the 17 clones induced multiple NIH 3T3 cell tumors in recipient nude mice. Southern blot analyses showed the presence of human Alu repetitive sequences in all of the NIH 3T3 tumor cell DNAs. Intact, human HRAS sequences were observed in 2 of the 11 tumor groups, whereas no hybridization was detected when human KRAS or NRAS probes were used. Slow-migrating ras p21 proteins, consistent with codon 12 mutations, were observed i in the same two NIH 3T3 tumor cell groups that contained the human HRAS bands. Genomic DNA from one of these two human anchorage-independent cell populations (clone 21A) was used to enzymatically amplify a portion of exon 1 of the HRAS gene. Direct sequence analysis of the amplified DNA indicated equal presence of a wild-type (GGC) and mutant (GTC) allele of the HRAS gene. The results demonstrate that exposure of normal human cells to a common environmental mutagen yields HRAS GC----TA codon 12 transversions that have been commonly observed in human tumors. This oncogene as well as yet to be identified oncogene are also shown to stably confer anchorage-independence to human cells.     

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.     

Amplification of the proto-neu oncogene facilitates oncogenic activation by a single point mutation.

To determine whether the amplification of the proto-neu oncogene (also called c-erbB-2) plays a role in tumorigenicity, we previously generated an NIH 3T3 transfectant (DHFR/G-8) that carried the amplified proto-neu gene. The DHFR/G-8 cells exhibited normal morphology. Their growth curve was similar to that of NIH 3T3 cells but was different from that of the B104-1 cell, and NIH 3T3 transfectant that carries the activated neu oncogene. When injected into nude mice, B104-1 cells produced tumors within 2 weeks, whereas the DHFR/G-8 cells did not produce tumors until 3 months after injection, and the NIH 3T3 cells did not produce any tumors even after 3 months. The tumors produced by the injection of the DHFR/G-8 cells were excised and grown in culture. The cells derived from the tumors were of transformed morphology and highly tumorigenic. The DNAs from the tumor cells were transfected into NIH 3T3 cells. The transfection resulted in foci on the NIH 3T3 monolayer. Southern analysis indicated that the foci derived from the transfection contained the neu gene. Using oligonucleotides as probes, the neu gene in the foci was found to carry a single-point mutation identical to the one previously found in the rat neuroblastoma and glioblastoma induced by the ethylnitrosourea. We conclude that the DNA region encoding the transmembrane domain of neu is a hot spot for converting the proto-neu gene into an activated oncogene and that amplification of the proto-neu gene facilitates mutation of the hot spot.     

Detection of a raf-related and two other transforming DNA sequences in human tumors maintained in nude mice.

High molecular weight DNAs prepared from a variety of human tumors maintained in nude mice were assayed for their ability to transform NIH 3T3 cells. DNAs from 4 of 21 tumors tested induced transformed foci in cultures of NIH 3T3 cells. They were from a Ewing sarcoma line, a glioblastoma line, a leiomyosarcoma line, and a lung carcinoma line. Hybridization analyses of the NIH 3T3 transformant DNAs with a human repetitive sequence as probe revealed that four distinct transforming DNA sequences were transferred to NIH 3T3 cells from the four tumor lines. The transforming DNA in a lung carcinoma line was a human homologue of the oncogene of Kirsten murine sarcoma virus (Ki-ras). On the other hand, the three other transforming DNAs showed no similarity to any known human transforming gene detected by the NIH 3T3 transformation assay. Further analyses with a series of cloned oncogenes as probes revealed that the transforming DNA in a glioblastoma line was a human homologue of the oncogene of 3611-murine sarcoma virus (raf). However, the two transforming DNAs in a Ewing sarcoma line and a leiomyosarcoma line had no sequence homology to any of the cloned oncogenes.     

Identification of an antigen associated with transforming genes of human and mouse mammary carcinomas.

Sera from tumor-bearing mice immunoprecipitated a 86,000-dalton glycoprotein from extracts of NIH cells transformed by human mammary carcinoma DNA. This antigen was not immunoprecipitated from extracts of NIH 3T3 cells, spontaneously transformed NIH cells, NIH cells transformed by normal human DNA, NIH cells transformed by human bladder carcinoma DNA, or NIH cells transformed by Rous sarcoma virus DNA. In addition, sera from mice bearing tumors induced by NIH cells transformed by either normal human DNA or human bladder carcinoma DNA did not immunoprecipitate this antigen from extracts of NIH cells transformed by human mammary carcinoma DNA. However, this antigen was immunoprecipitated by sera from mice bearing tumors induced by NIH cells transformed by mouse mammary carcinoma DNAs and from mice bearing primary mammary carcinomas. These results indicate that this glycoprotein represents an antigen that is specifically associated with expression of the transmissible transforming genes of human and mouse mammary carcinomas.     

Benzo[a]pyrene-induced murine skin tumors exhibit frequent and characteristic G to T mutations in the p53 gene.

Human tobacco-related cancers exhibit a high frequency of G to T transversions in the mutation hot spot region of the p53 tumor suppressor gene, possibly the result of specific mutagens in tobacco smoke, most notably benzo[a]pyrene (B[a]P). No in vivo animal model of B[a]P-induced tumorigenesis has been used, however, to substantiate these molecular epidemiological data experimentally. Direct DNA sequence analysis of the hot spot region (exons 5-8 inclusive) of murine p53 was performed in 20 skin tumors induced by a complete carcinogenesis protocol with B[a]P. Sequence analyses revealed numerous heterozygous missense mutations in carcinomas, specifically in exons 7 and 8 of the p53 gene, and targeting exclusively guanine residues. Moreover, 70% (5/7) of the mutations characterized were G to T transversions. In contrast, direct DNA sequence analysis of 36 skin tumors induced by 7,12-dimethylbenz[a]anthracene (DMBA) in either a complete carcinogenesis protocol or in a two-stage carcinogenesis protocol revealed a 30% frequency of heterozygous p53 mutations, with the majority of mutations found in carcinomas, but only a single G to T transversion (1/8). Thus, while mutation frequencies are similar, the pattern and type of p53 mutations in B[a]P-induced skin tumors differs significantly from the mutation spectra in DMBA-induced squamous neoplasias. These in vivo findings in B[a]P-induced tumors lend support to in vitro and molecular epidemiological evidence, suggesting that the p53 tumor suppressor gene may be a selective target of metabolically activated B[a]P species etiologically associated with human tobacco-related cancers.     

Transformation of rodent immortalized and embryo cells by oncogenes. I. Mouse (NIH 3T3) and rat (FR 3T3) immortalized fibroblasts

Immortalized mouse NIH 3T3 cells were transformed by gene transfer of DNA isolated from a human bladder tumor cell line and plasmids containing an activated human Ha-ras oncogene insert. For gene transfer the calcium-phosphate co-precipitation method was used. Transformation was evaluated by morphological focus formation, growth in soft agar and tumor development in nude mice. In addition, immortalized rat FR 3T3 cells were transformed by Ha-ras, too. The co-transfer of ras and myc oncogenes did not enhance focus formation in FR 3T3 cells.     

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.     

Transforming genes of human bladder and lung carcinoma cell lines are homologous to the ras genes of Harvey and Kirsten sarcoma viruses.

Blot hybridization analysis indicated that NIH 3T3 mouse bladder transformed by high molecular weight DNAs of a human bladder and a human lung carcinoma cell line contained new sequences homologous, respectively, to the transforming genes of Harvey (rasH) and Kirsten (rasK) sarcoma viruses. The unique ras sequences were present in multiple independent NIH cell lines transformed in both primary and secondary transfection assays and corresponded to ras sequences normally present in human DNAs. The ras gene product was expressed in NIH cells transformed by bladder carcinoma DNAs and in the human bladder carcinoma cell lines at levels 2- to 4-fold greater than the level observed in nontransformed NIH 3T3 cells. These results indicate that the transforming genes of these human tumor cell lines are the cellular homologs of two retroviral transforming genes.     

Detection of mutant Ha-ras genes in chemically initiated mouse skin epidermis before the development of benign tumors.

An activated Ha-ras oncogene has been consistently found in chemically initiated benign and malignant mouse skin tumors, and an activated ras oncogene has been shown to initiate the process of mouse skin carcinogenesis. However, the exact timing of mutational activation of the Ha-ras gene relative to application of the chemical carcinogen is not known. A sensitive mutation-specific PCR technique was used to experimentally address the timing of Ha-ras gene mutational activation. This technique can detect mutant Ha-ras alleles in the presence of a very large excess of normal ras alleles. Activated Ha-ras genes with 61st codon A----T mutations were found in the epidermis of mice 1 week after topical initiation with 7,12-dimethylbenz[a]anthracene or urethane by using this assay. These results were confirmed by Xba I restriction fragment length polymorphism analysis and direct DNA sequencing. One week after initiation is 1-2 months before the appearance of benign papillomas that harbor activated Ha-ras oncogenes when the initiated mice are promoted with the tumor promoter phorbol 12-myristate 13-acetate. Our data support the hypothesis that initiated epidermal cells containing an activated Ha-ras gene can remain dormant in the skin until a tumor promoter induces regenerative hyperplasia that allows for outgrowth of these cells with an activated ras oncogene to give rise to a benign papilloma.     

Transforming activity of human tumor DNAs.

High molecular weight DNAs of 26 human tumors and tumor cell lines were assayed for the presence of transmissible activated transforming genes by transfection of NIH 3T3 mouse cells. DNAs of two bladder carcinoma cell lines induced transformation with high efficiencies (approximately 0.2 transformant per microgram of DNA), whereas DNAs of the other tumors studied lacked detectable transforming activity. These findings suggest that dominant mutations or gene rearrangements can result in the activation of cellular transforming genes in some human tumors.     

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.     

The human Ha-ras oncogene induces genomic instability in murine fibroblasts within one cell cycle.

Many human tumors contain an activating mutation in one of the ras protooncogenes. Additionally, these tumor cells are often heteroploid and characterized by chromosome breaks and rearrangements that are consequences of the genomic instability that is thought to contribute to tumor progression. The concurrence of ras mutations and genomic instability in tumors prompted us to ask whether selective induction of an activated Ha-ras gene could render a genome unstable. The NIH 3T3 cells used in this study contained mutant p53 genes and carried a selectively inducible activated (EJ) Ha-ras transgene under the control of bacterial lactose regulatory elements. When stably transfected cells were induced to express activated Ha-ras by isopropyl beta-D-thiogalactoside administration, there was a marked increase in the number of gross chromosomal aberrations including acentric fragments, multicentric chromosomes, and double minutes, which occurred within the time frame of a single cell cycle from the time of induction. To confirm that these aberrations occurred within the first cell cycle after mutant Ha-ras induction, the cells were arrested in G1 phase by serum depletion and, subsequently, released by administration of isopropyl beta-D-thiogalactoside or serum. The mitoses from cells released with isopropyl beta-D-thiogalactoside contained a 3-fold elevation in the fraction of chromosomes containing aberrations compared to mitoses from parallel cell cultures that were released with serum. Thus, the induction of activated Ha-ras gene expression in these cells results in genomic instability that can be detected as aberrant chromosomes at the next mitosis.     

Passage of phenotypes of chemically transformed cells via transfection of DNA and chromatin.

DNA was prepared from 15 different mouse and rat cell lines transformed by chemical carcinogens in vitro and in vivo. These DNAs were applied to NIH3T3 mouse fibroblast cultures by using the calcium phosphate transfection technique. DNAs of five donor lines were able to induce foci on the recipient monolayers. Ten other donor DNAs yielded few or no foci. DNAs from control, nontransformed parental cell lines induced few or no foci. Chromosomes were transfected from one donor whose naked DNA was unable to induce foci, and morphologic transformation of recipients was observed. These experiments prove that in five of these cell lines the chemically induced phenotype is encoded in DNA, and the sequences specifying the transformed phenotype behave as a dominant allele in the NIH3T3 recipient cells. The sequences encoding the transformation are likely found on a single fragment of DNA.     

Transformation of human cells by DNAs ineffective in transformation of NIH 3T3 cells.

Neonatal human foreskin fibroblasts can be transformed to anchorage-independent growth by transfection with DNAs inefficient in transforming NIH 3T3 cells. Human cells transfected with DNA from GM 1312, a multiple myeloma cell line, or MOLT-4, a permanent lymphoblast line, grow without anchorage at a much higher frequency than do the parental cells and their DNAs can transform human cell recipients to anchorage-independent growth; they have extended but not indefinite life spans and are nontumorigenic. Human fibroblasts are also transformed by DNAs from two multiple myeloma lines that also transform 3T3 cells; however, restriction analysis suggests that different transforming genes in this DNA are acting in the human and murine systems. These results indicate that the human cell transfection system allows detection of transforming genes not effective in the 3T3 system and points out the possibility of detection of additional transforming sequences even in DNAs that do transform murine cells.