Carcinogens with diverse mutagenic activities initiate neoplastic guinea pig cells that acquire the same N-ras point mutation

The role of selection in progressive neoplastic transformation

Mathematical modeling indicates that selective growth of cells with biallelic mutations in tumor suppressor genes is the driving force in the development of most human tumors, and that increased mutation rate is not required. Spontaneous neoplastic transformation of cells in culture offers the opportunity for quantitative analysis of all stages of neoplastic progression, the cellular variation that underlies it, and the selective conditions that promote it. Most of the early work on spontaneous transformation was done in primary cultures of mouse embryo cells, but established mouse cell lines have been used more in recent years. The main criteria for transformation have been tumorigenesis in mice, increase in saturation density, and production of discrete, multilayered foci in confluent cell cultures. Spontaneous transformation in NIH 3T3 mouse fibroblasts is efficiently evoked by progressive selection under prolonged contact inhibition at high population density or during multiplication at low population density in suboptimal concentrations or types of serum. In general, it is a multistep process with some stages of progression occurring before there is any visible sign of transformed foci. There is a high degree of heritable heterogeneity in the original NIH 3T3 cell population for susceptibility to transformation. Isolation and expansion of minority susceptible clones from a relatively refractory population exhibit transformation long before the polyclonal parental population does because of the increased proportion of susceptible cells in these clones. There are indications that the selective conditions induce selectable variants. Tumor development in animals and man shares important characteristics with spontaneous transformation in culture, including a major role for selection, but the selective conditions for clonal expansion probably vary with the dynamics of differentiation in each tissue. These considerations support a role for an altered microenvironment (as in the aging process) in selective growth of rogue clones.

High sequence similarity within ras exons 1 and 2 in different mammalian species and phylogenetic divergence of the ras gene family

We have determined the canine and feline N-, K-, and H-ras gene sequences from position +23 to +270 covering exons I and II which contain the mutational hot spot codons 12, 13, and 61. The results were used to assess the degree of similarity between ras gene DNA regions containing the critical domains affected in neoplastic disorders in different mammalian species. The comparative analyses performed included human, canine, feline, murine, rattine, and, whenever possible, bovine, leporine (rabbit), porcelline (guinea pig), and mesocricetine (hamster) ras gene sequences within the region of interest. Comparison of feline and canine nucleotide sequences with the corresponding regions in human DNA revealed a sequence similarity greater than 85% to the human sequence. Contemporaneous analysis of previously published ras DNA sequences from other mammalian species showed a similar degree of homology to human DNA. Most nucleotide differences observed represented synonymous changes without effect on the amino acid sequence of the respective proteins. For assessment of the phylogenetic evolution of ras gene family, a maximum parsimony dendrogram based on multiple sequence alignment of the common region of exons I and II in the N-, K-, and H-ras genes was constructed. Interestingly, a higher substitution rate among the H-ras genes became apparent, indicating accelerated sequence evolution within this particular clade. The most parsimonious tree clearly shows that the duplications giving rise to the three ras genes must have occurred before the mammalian radiation.

A 79 amino acid oncogene is responsible for human cytomegalovirus mtrII induced malignant transformation

Human cytomegalovirus (HCMV) morphological transforming region (mtr)II is the only HCMV mtr that was retained and expressed in transformed mouse or rat cells. The minimal transforming region has previously been shown to be within a 980-bp BanII/XhoI subfragment which encodes three open reading frames (ORF) of 34, 79, and 83 amino acids. This report provides definitive evidence that the 79-aa ORF is responsible for mtrII mediated tumorigenic transformation. The 79-aa ORF, subcloned into a mammalian expression vector, pCHC79orf, induced morphologic transformation of NIH 3T3 cells. These transformed cells expressed 79-aa ORF specific transcripts and were tumorigenic when injected into nude mice. A construct containing a triple termination linker inserted after codon 24 failed to transform NIH 3T3 cells to tumorigenicity even though 79-aa ORF specific transcripts were expressed. Furthermore, when the triple termination linker was inserted after codon 49, tumorigenic transformation still occurred. These results demonstrate that the 79-aa ORF is the oncogene within HCMV mtrII and that the first 49-aa are sufficient.

Sequencing analysis of Ha-, Ki-, and N-ras genes in rat urinary bladder tumors induced by N-[4-(5-nitro-2-furyl)-2-thiazolyl]formamide (FANFT) and sodium saccharin

Male F344 rats were fed N[4-(5-nitro-2-furyl)-2-thiazolyl]formamide (FANFT) for up to 4 wk, then given the basal diet with or without 5% sodium saccharin for up to 100 wk. In a previous study, we demonstrated point mutations in codons 12 and 61 of Ha-ras gene among eleven transitional cell carcinomas (TCC), one undifferentiated carcinoma, and two sarcomas of the urinary bladder (Mol Carcinogen 3:210-215, 1990). In this study, Ha-ras, Ki-ras, and N-ras sequences were examined by polymerase chain reaction (PCR) and direct DNA sequencing. The results confirm the point mutation in codon 61 (CAA to CGA in 5 TCCs and to CTA in one TCC) of the Ha-ras gene. Mutation at codon 12 was not confirmed. No mutation was found in the Ki-ras gene. Sequences of the N-ras gene exons 1 and 2 were determined, and no mutations was detected. These results suggest the involvement of activated Ha-ras gene, but not Ki-N or N-ras gene, in rat urinary bladder carcinogenesis induced by FANFT. Subsequent sodium saccharin administration did not affect the changes in Ha-ras gene.

Multiplex polymerase chain reaction amplification and direct sequencing of homologous sequences: point mutation analysis of the ras genes

ras proto-oncogenes are activated by point mutation in a wide variety of human and animal tumors, making ras gene analysis a major area of clinical and basic cancer research. Activating point mutations, in each of the three ras genes (Ha-, Ki-, or N-ras), usually occur in one of three specific codons (12, 13, or 61). Thus, an adequate assessment of activating ras gene mutations should include the analysis of at least nine codons. We have developed a rapid method for point mutation analysis of the ras genes, which involves simultaneous (multiplex) PCR amplification of all three homologous ras genes (in the regions surrounding codons 12-13 and codon 61) in a single reaction starting with only 1 microgram of genomic DNA. Although multiplex PCR has been previously used for unrelated sequences, we demonstrate here that multiplex PCR can also be used for highly homologous sequences. Importantly, after coamplification, each of the homologous ras genes can be individually and specifically sequenced even though the other two closely related genes are present in the same template mixture, by using high-stringency conditions permitted by Taq DNA polymerase. An automated multicycle DNA sequencing procedure is used to allow the double-stranded PCR products to be sequenced directly without the need to generate single-stranded templates, further simplifying the protocol. Our multiplex PCR amplification and direct DNA sequencing procedures should greatly facilitate more complete analyses of activating ras gene point mutations, particularly in studies involving many tumor samples.(ABSTRACT TRUNCATED AT 250 WORDS)

Sequence specificity in the reaction of benzopyrene diol epoxide with DNA

Benzopyrene diol epoxide (BPDE; (+)-7R,8S-dihydroxy-9S,10R-epoxy-7,8,9,10-tetrahydrobenzo[a]pyrene), the ultimate carcinogen derived from the polycyclic hydrocarbon benzo[a]pyrene, reacts principally with the guanine bases in DNA. Nineteen double stranded, self-complementary oligonucleotides, containing deoxyguanosine in various sequence contexts, were each treated with tritium labelled BPDE. The extent of reaction was determined by releasing the BPDE-guanine adduct with acid, isolating it by chromatography on a reverse-phase column, and estimating it by its radioactivity. Oligonucleotides containing an isolated guanine, such as AAGTACTT, were little affected by BPDE. Reactivity was increased where the guanine was flanked by another guanine on the same strand (e.g. TACCTAGGTA) or on the complementary strand (e.g. TATTCGAATA), and was highest in mixed G-C sequences such as ATCCGGAT. The results should help predict major sites of attack of BPDE on cellular proto-oncogenes.

Activation of ras oncogenes in chemically transformed BALB/MK-2 mouse keratinocytes

BALB/MK-2 cells are an epidermal growth factor (EGF)-dependent cell line derived from BALB/c mouse epidermis that can undergo terminal differentiation under appropriate conditions. Previous studies have shown that transformation of these cells by retroviral oncogenes relieves the EGF requirement while blocking the terminal differentiation program. In this report we show that BALB/MK-2 cells are sensitive to transformation by the chemical carcinogens dimethylbenz[a]anthracene (DMBA), 3-methylcholanthrene (MCA), and N-methyl-N'-nitro-N'-nitroso-guanidine (MNNG). BALB/MK-2 cells transformed by these carcinogens proliferate in the absence of EGF and do not undergo terminal differentiation in response to calcium. However, the cells retain their anchorage growth dependence and are nontumorigenic in nude mice. NIH 3T3 transfection analysis showed that the endogenous Ha-ras gene had been activated in both DMBA- and MNNG-transformed cells and the Ki-ras gene had been activated in the MCA-transformed cells. Additionally, non-ras transforming activity was detected in some MNNG-transformed BALB/MK-2 cells. Thus, the BALB/MK-2 cell line provides a reproducible in vitro assay system for chemical transformation of epithelial cells and for identification of oncogene activations associated with changes in growth control and differentiation.

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.

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 less than 0.0008 foci/microgram DNA, while approximately 40% (5 of 12) of the DNAs from carcinogen-induced, tumorigenic hamster cell lines induced foci at a frequency of greater than or equal to 0.012 foci/microgram DNA. The other seven carcinogen-induced cell lines and the BHK-A cells were negative (less than 0.002 foci/microgram 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/microgram 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.(ABSTRACT TRUNCATED AT 250 WORDS)