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.     

A method to detect and characterize point mutations in transcribed genes: amplification and overexpression of the mutant c-Ki-ras allele in human tumor cells.

A significant percentage of human tumors contain activated ras oncogenes that have acquired oncogenic potential as a result of somatic point mutations at codon 12 or 61 of the encoded ras gene product. We report here a method to detect and characterize mutations in ras genes that is based on the ability of pancreatic ribonuclease (RNase A; EC 3.1.27.5) to cleave RNA heteroduplexes containing single-base mismatches. Using this method, we show that certain human tumor cells contain mutant c-Ki-ras genes, and we define the nature and position of these mutations. At the same time, we describe the presence and estimate the expression of both normal and mutant c-Ki-ras alleles in the same tumor cells. This method should be useful for the diagnostic detection and characterization of single point mutations in expressed genes.     

Mutations activating human c-Ha-ras1 protooncogene (HRAS1) induced by chemical carcinogens and depurination.

In vitro modification of plasmids containing the human c-Ha-ras1 protooncogene (HRAS1) with the ultimate carcinogens N-acetoxy-2-acetylaminofluorene and r-7, t-8-dihydroxy-t-9, 10-epoxy-7,8,9,10-tetrahydrobenzo[alpha]pyrene (anti-BPDE) generated a transforming oncogene when the modified DNA was transfected into NIH 3T3 cells. The protooncogene was also activated by heating the plasmid at 70 degrees C, pH 4, to generate apurinic/apyrimidinic sites in the DNA. DNA isolated from transformed foci was analyzed by hybridization with 20-mer oligonucleotides designed to detect single point mutations within two regions of the gene commonly found to be mutated in tumor DNA. Of 23 transformants studied, 7 contained a mutation in the region of the 12th codon, whereas the remaining 16 were mutated in the 61st codon. Of the codon-61 mutants, 6 were mutated at the first base position (C X G), 5 at the second (A X T), and 5 at the third (G X C). The point mutations induced by anti-BPDE were predominantly G X C----T X A and A X T----T X A base substitutions, whereas four N-acetoxy-2-acetylaminofluorene-induced mutations were all G X C----T X A, and a single depurination-induced activation that was analyzed contained an A X T----T X A transversion. Together, these methods provide a useful means of determining point mutations produced by DNA-damaging agents in mammalian cells.     

Absence of oncogene amplifications and occasional activation of N-ras in lymphoblastic leukemia of childhood

To examine whether determination of (1) the copynumber or restriction pattern of certain oncogenes or (2) the mutational activation of the N-ras gene might contribute to the risk classification of acute lymphoblastic leukemia of childhood (ALL), we investigated DNA isolated from lymphoblasts of untreated patients. Restriction enzyme analysis of cellular oncogenes was performed on DNA of 25 patients. No rearrangements could be demonstrated within or near the genes c-myc, c-myb, c-abl, bcr, c-Ki-ras, and N-ras. No amplifications of these genes nor of N-myc or c-Ha-ras were present. Eight of 21 patients were heterozygote for "rare" Ha-ras allelic restriction fragments that have been associated with an increased risk of developing a malignancy. These patients were clinically indistinguishable from patients lacking these fragments. The breakpoint cluster region (bcr) that is rearranged in all patients with Philadelphia chromosome positive chronic myeloid leukemia, was normal in all cases, including at least one patient with Philadelphia chromosome positive ALL. A 2.8 kb HindIII fragment of a hitherto unknown gene or pseudogene related to v-myb probably derives from the Y chromosome. Nineteen patients were examined for point mutations in the N-ras gene, using a novel synthetic oligonucleotide hybridization assay. In two patients activating point mutations were present, both in positions 1 of the 12th codon. Both patients were somewhat older than the others (16 and 11 years), had L2 morphology, and were shown to have high growth fractions of tumor in their bone marrow.     

Identification of an activated c-Ki-ras oncogene in rat liver tumors induced by aflatoxin B1.

Weanling male Fischer rats were administered 40 intraperitoneal injections of aflatoxin B1 (25 micrograms per animal per day) over a 2-month period. This chronic dosing regimen resulted in the sequential formation of hyperplastic foci, preneoplastic nodules, and hepatocellular carcinomas in all of the animals treated. The presence of transforming DNA sequences was detected by formation of anchorage-independent foci after transfection of tumor-derived DNA in NIH 3T3 mouse fibroblasts. Transfection of genomic DNA isolated from individual tumors from eight animals resulted in specific transforming activities ranging from 0.05 to 0.2 foci per micrograms of DNA. Primary transfectant DNAs were analyzed by Southern blot hybridization with DNA probes homologous to c-Ha-ras, c-Ki-ras, and N-ras oncogenes. A highly amplified c-Ki-ras oncogene of rat origin was detected in transformants derived from tumors in two of the eight animals tested. There was no evidence to suggest the presence of c-Ha-ras or N-ras sequences in any of the transformants. Analysis of primary liver tumor DNA showed no Ki-ras DNA amplification when compared to control liver DNA samples. Increased levels of c-Ki-ras p21 proteins were detected in 3T3 transformants containing activated rat c-Ki-ras genes. The presence of c-Ki-ras sequences of rat origin capable of inducing transformed foci can be taken as evidence that the c-Ki-ras gene has been activated in the primary liver tumors.     

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.     

Activation of the c-Ki-ras oncogene in aflatoxin B1-induced hepatocellular carcinoma and adenoma in the rat: detection by denaturing gradient gel electrophoresis.

Sequence alterations in the exon 1 region of the rat c-Ki-ras gene were studied in DNA isolated from aflatoxin B1 (AFB1)-induced rat liver carcinomas and precursor lesions appearing 56 weeks after administration of the carcinogen. To detect the mutations with high sensitivity, DNA samples were analyzed by using polymerase chain reaction (PCR) amplification in conjunction with allele-specific oligonucleotide (ASO) hybridization together with a modified PCR-G+C clamp-denaturing gradient gel electrophoresis (DGGE) method. Mutations in the Ki-ras gene were present in all adenomas and carcinomas examined. The predominant mutation observed was a G.C-to-A.T base transition in codon 12 (GGT to GAT). Also present, but at low frequency, was a G.C-to-T.A base transversion in the same codon (GGT to TGT). In addition, 20% of the samples contained a G.C-to-T.A transversion in the second base position of codon 12 (GGT to GTT), a mutation not previously observed in AFB1-induced rat liver tumors. These results confirm and extend our previous findings that Ki-ras mutation is a prevalent event in hepato-cellular carcinogenesis induced in Fischer 344 rats by AFB1. The modified DGGE method described is applicable to the screening of multiple mutations in neoplastic lesions with high fidelity and sensitivity.     

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.     

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.     

RAS gene mutations in acute and chronic myelocytic leukemias, chronic myeloproliferative disorders, and myelodysplastic syndromes.

We report on investigations aimed at detecting mutated RAS genes in a variety of preleukemic disorders and leukemias of myeloid origin. DNA transfection analyses (tumorigenicity assay) and hybridization to mutation-specific oligonucleotide probes established NRAS mutations in codon 12 or 61 of 4/9 acute myelocytic leukemias (AML) and three AML lines. Leukemic cells of another AML patient showed HRAS gene activation. By using a rapid and sensitive dot-blot screening procedure based on the combination of in vitro amplification of RAS-specific sequences and oligonucleotide hybridization we additionally screened 15 myelodysplastic syndromes, 26 Philadelphia chromosome-positive chronic myelocytic leukemias in chronic or acute phase, and 19 other chronic myeloproliferative disorders. A mutation within NRAS codon 12 could thus be demonstrated in a patient with idiopathic myelofibrosis and in another with chronic myelomonocytic leukemia. Moreover, mutated NRAS sequences were detected in lymphocytes, in granulocytes, as well as in monocytes/macrophages of the latter case.     

A position 12-activated H-ras oncogene in all HS578T mammary carcinosarcoma cells but not normal mammary cells of the same patient.

Among 21 human mammary tumors analyzed for transforming genes by transfection of NIH/3T3 cells, only DNA of a carcinosarcoma cell line, HS578T, registered as positive. A Harvey (H)-ras oncogene identified in this line was cloned in biologically active form and the activating lesion was identified as a single nucleotide substitution of adenine for guanine in the 12th codon. This results in substitution of aspartic acid for glycine at this position of the p21 coding sequence. Knowledge that this alteration creates a restriction site polymorphism for Msp I/Hpa II in the H-ras protooncogene made it possible to survey for the presence of the activated H-ras allele in normal cells as well as in clonally derived tumor cell lines of the same patient. We demonstrated the presence of unaltered H-ras alleles in normal HS578 cells. In contrast, every clonally derived HS578T tumor cell line analyzed contained the H-ras oncogene possessing the genetic alteration at position 12. These findings establish that activation of this oncogene was the result of a somatic event selected within all HS578T tumor cells.     

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.     

Spontaneous activation of a human proto-oncogene.

It has been recently shown that malignant activation of the c-has/bas proto-oncogene in T24 human bladder carcinoma cells was mediated by a single point mutation. A deoxyguanosine located at position 35 of the first exon of this proto-oncogene was substituted by thymidine. These findings predicted that the resulting oncogene would code for a structurally altered p21 protein containing valine instead of glycine as its 12th amino acid residue. We now report the spontaneous activation of the human c-has/bas proto-oncogene during transfection of NIH/3T3 cells. As in T24 cells, this in vitro activated oncogene also acquired malignant properties by a single point mutation. In this case we have detected a G leads to A transition, which occurred at the same position as the mutation responsible for the activation of the T24 oncogene. These results predict that the p21 protein coded for by the spontaneously activated c-has/bas gene will incorporate aspartic acid as its 12th amino acid residue. Computer analysis of the secondary structure of c-has/bas encoded p21 proteins indicates that substitution of the glycine residue located at position 12, not only by aspartic acid or valine but also by any other amino acid, would result in the same structural alteration. These findings indicate that a specific conformational change is sufficient to confer transforming properties to this p21 protein. Moreover, they predict that any mutation affecting the coding properties of the 12th codon of the c-has/bas proto-oncogene will lead to its malignant activation.     

Hypomethylation of the c-myc oncogene in liver cirrhosis and chronic hepatitis

In order to investigate how chronic liver diseases, including liver cirrhosis and chronic hepatitis, are associate with hepatocarcinogenesis in terms of gene alteration, the methylation states of the c-myc and c-Ki-ras genes were examined in 34 liver tissues from patients with chronic liver disease without hepatocellular carcinoma (HCC), 34 non-tumor liver tissues from patients with HCC, 18 HCC tissues and 31 control liver tissues. The methylation states were analyzed by the Southern hybridization method using the restriction endonuclease isoschizomers MspI and HpaII. The CCGG sites at the second exon of the c-myc gene tended to be more extensively hypomethylated both in chronic liver disease and in non-tumor tissues than in control livers. Whereas the CCGG sites of the c-Ki-ras, and the third exon of the c-myc gene tended to be hypomethylated only in HCC tissues in comparison with other tissue groups. These results suggest that chronic liver disease may be situated between normal liver and HCC based on the state of DNA methylation and associated with the development of HCC through hypomethylation of the c-myc and/or c-Ki-ras gene.     

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.