Oncogenic potential of c-erbB-2 and its association with c-K-ras in premalignant and malignant lesions of the human uterine endometrium.

The aim of this study was to detect activated c-K-ras by gene point mutation and to find c-erbB-2 gene amplification with p185 expression in association with the c-K-ras gene product p21 in the human endometrium. Specimens obtained from 25 normal, 31 hyperplastic and 72 malignant samples of the human endometrium were examined for point mutation in codons 12, 13 and 61 of the c-K-ras by direct sequencing and c-erbB-2 gene amplification with p185 and p21 expression by differential polymerase chain reaction (DPCR) and immunohistochemistry. Neither the normal endometrium nor endometrial hyperplasias were found to have mutations in the c-K-ras gene, although a double mutation of codons 12 and 13 as a single-point mutation was observed in one case of endometrioid carcinoma (2.8%). In each of two other cases of endometrioid carcinoma (2/72), two single-point mutations of codon 13 (5.6%) were shown. Using DPCR, we found c-erbB-2 to be amplified in 15 premalignant (48%) and 45 malignant (63%) samples. We noticed that nonamplification of the c-erbB-2 gene was associated with the absence of immunoreactivity. Our data indicate that, while c-erbB-2 plays a role in the early development of endometrioid carcinomas, c-K-ras gene activation by point mutation does not.     

Detection of ras gene mutations in human lung cancers by single-strand conformation polymorphism analysis of polymerase chain reaction products

A simple, sensitive method of DNA analysis of nucleotide substitutions, namely, single-strand conformation polymorphism analysis of polymerase chain reaction products (PCR-SSCP analysis), was used for detection of mutated ras genes in surgical specimens of human lung cancer. Of a total of 129 tumors analysed, 22 contained a mutated ras gene. Of the 66 adenocarcinomas analysed, 14 contained an activated c-Ki-ras2 gene (the mutations in codon 12 in 6, in codon 13 in 4, in codon 18 in one, and in codon 61 in 3), one contained a c-Ha-ras1 gene with a mutation in codon 61 and 3 contained N-ras genes with mutations (in codon 12 in one and in codon 61 in 2). Mutated rats genes were also found in 2 of 36 squamous cell carcinomas (c-Ha-ras1 genes with mutations in codon 61) and 2 of 14 large cell carcinomas (c-Ki-ras2 genes with mutations in codon 12). No mutation of the ras gene was detected in 8 small cell carcinomas and 5 adenosquamous cell carcinomas. These results indicate that activation of the ras gene was not frequent (17%) in human lung cancers, that among these lung cancers mutation of the ras gene was most frequent in adenocarcinomas (27%) and 73% of the point mutations were in the c-Ki-ras2 gene in codon 12, 13, 18 or 61.     

ras oncogene activation in human ovarian carcinoma

Samples of 37 fresh human ovarian tumor biopsies were screened to detect proto-oncogene amplification and ras mutations. Three samples showed c-K-ras2 amplification; none of the other oncogenes tested revealed any gene amplification. 5-, 25-, and 120-fold amplifications were assessed by dilution experiments and soft laser densitometry. Corresponding elevated levels of c-K-ras2 mRNA and p21 ras protein were found in the three tumors. Analysis by the polymerase chain reaction method to detect point mutations of codon 12 or codon 61 of Harvey-, Kirsten-, or N-ras showed only the wildtype sequence in all specimens. No correlation was found between ras activation and degree of tumor progression or histological subtype. DNA from one of the tumors with c-K-ras2 amplification proved to have high transforming activity in the NIH 3T3 tumorigenicity assay, but the transforming gene was not c-K-ras2.     

Analysis of oncogene alterations in human endometrial carcinoma: prevalence of ras mutations

The molecular genetics of human endometrial carcinoma have yet to be defined to any significant extent. Cell lines from 11 endometrial carcinomas were examined for alterations in proto-oncogenes that might predictably be present, based on existing data from the better-characterized human carcinomas of the uterine cervix, ovary, and breast. Codons 12, 13, and 61 of the Ha-ras, Ki-ras, and N-ras genes were examined for possible point mutations, and the c-erbB2/neu, c-myc, and epidermal growth factor receptor (EGFR) genes were examined for amplification or overexpression. Ras mutations were found in seven of 11 (64%) tumors, including three in codon 61 of Ha-ras (CAG----CAT) and four in codon 12 of Ki-ras (GGT----GAT in two and GGT----GTT in two). No evidence was found for amplification or overexpression of the c-erbB2 or EGFR genes in any tumor. One tumor contained amplified c-myc sequences and exhibited relative overexpression of c-myc. These data suggest that the amplification or overexpression of several proto-oncogenes frequently observed in other human gynecologic and breast tumors are not prevalent in endometrial carcinoma and that ras gene mutations are relatively common in this tumor type.     

Analysis of ras gene mutations in biliary and pancreatic tumors by polymerase chain reaction and direct sequencing

Ras gene is one of the oncogenes most commonly detected in human cancers and consists of three families (H-ras, K-ras, N-ras) that are converted to active oncogenes by point mutations occurring in codon 12, 13, or 61. The authors analyzed mutations of these codons in 12 extrahepatic bile duct carcinomas, nine gallbladder carcinomas, and 20 pancreatic tumors (18 pancreatic adenocarcinomas and two islet cell tumors) by a method to directly sequence nucleotides, using polymerase chain reaction and a direct sequencing method. Point mutations at K-ras codon 12 were found in all of 18 pancreatic adenocarcinomas and in one bile duct carcinoma, but there were no mutations in the remaining 11 bile duct carcinomas, in all of 9 gallbladder carcinomas, or in two islet cell tumors. A very high incidence of ras gene mutations may be used clinically for the diagnosis of debatable cases of pancreatic adenocarcinoma.     

Analysis of ras gene mutations in human hepatic malignant tumors by polymerase chain reaction and direct sequencing

The ras gene is one of the oncogenes most commonly detected in human cancers, and it consists of three families (H-ras, K-ras, N-ras). These genes are converted to active oncogenes by point mutations occurring in either codon 12, 13, or 61. We analyzed mutations of these codons in 23 primary hepatic malignant tumors (12 hepatocellular carcinomas, nine cholangiocarcinomas, and two hepatoblastomas) by a method to directly sequence nucleotides, using polymerase chain reaction and a direct sequencing method. Of 23 hepatic malignant tumors, point mutations at K-ras codon 12 or K-ras codon 61 were found in six of nine cholangiocarcinomas. In contrast, there were no point mutations in any of 12 hepatocellular carcinomas or two hepatoblastomas around codon 12, 13, or 61 of the ras genes. These observations suggest that ras gene mutations are not related to pathogenesis of hepatocellular carcinoma, but play an important role in pathogenesis of cholangiocarcinoma.     

Colon carcinoma K-ras 2 oncogene of a familial polyposis coli patient

The DNA of a colon carcinoma-derived cell line (KMS-4) and that of skin fibroblasts from a familial polyposis coli patient were transfected into NIH3T3 cells in order to detect oncogenes associated with the disease. No transformation was observed with the normal skin fibroblast DNA, while the KMS-4 cell DNA was able to transform NIH3T3 cells. Through hybridization with known oncogene probes, the KMS-4 transforming gene was found to be a human activated c-K-ras 2 oncogene. Sequence analysis of the molecularly cloned KMS-4 c-K-ras 2 oncogene showed a single nucleotide transition from G to T at the 12th codon. This results in substitution of cysteine for glycine at this position. On using labeled synthetic oligonucleotides to detect the mutation in codon 12, we found the G to T transition in colon carcinoma cells. This suggests that activation of the c-K-ras 2 oncogene could be associated with colon carcinoma induction.     

Activation of c-K-ras is frequent in pancreatic carcinomas of Syrian hamsters, but is absent in pancreatic tumors of rats.

We have investigated the presence of mutations in ras genes at codons 12, 13 and 61 in chemically induced pancreatic tumors of rats and Syrian hamsters. Mutations were detected by means of allele-specific oligonucleotide hybridization to ras sequences amplified in vitro by the polymerase chain reaction. No mutations were observed in the c-K-ras gene or the c-H-ras gene of nine azaserine-induced adenomas and 15 carcinomas of the rat pancreas. This indicates that activated ras genes are not commonly involved in rat pancreatic cancer evolving from acinar cells. However, in 19 out of 20 ductular adenocarcinomas of hamster pancreas (95%), either codon 12 or 13 of the c-K-ras gene was mutated. This indicates that the activation of c-K-ras is a frequent event in the multistep process of pancreatic carcinogenesis induced by the alkylating carcinogen N-nitrosobis(2-oxopropyl)amine (BOP). The mutations of both codons were G----A transitions of the second base which is consistent with the type of mutation to be expected from DNA alkylation. Activation of the c-K-ras gene, therefore, may not only be a frequent but also an early event in hamster pancreas carcinogenesis. The frequent activation of the c-K-ras gene in both human and hamster pancreatic cancer emphasizes the relevance of BOP-induced pancreatic adenocarcinomas in Syrian hamsters as an experimental model system for studying human pancreatic cancer.     

Mutations in the p53 suppressor gene do not correlate with C-k-ras oncogene mutations in colorectal-cancer

Mutations in the p53 tumor suppressor gene have been analyzed in 196 colorectal tumors previously analyzed for mutations at codons 12 and 13 of the c-K-ras and N-ras oncogenes by a combination of Single Strand Conformation Polymorphism (SSCP) and Cycle Sequencing (CS) using total cellular RNA. Mutations were detected in 3 of 21 adenomas, 84 of 149 primary carcinomas, and 11 of 18 hepatic metastases. Over half of the tumors were homozygous for the mutant p53 allele at the mRNA level. Although deletions were detected in 5 tumors, missense mutations were the most frequent. The spectrum of 63 point mutations was heterogeneous, with all possible nucleotide substitutions ocurring at least once. No correlation was found between the spectrum of p53 gene mutations and the age, sex, race of the cancer patients or the anatomical localization of the tumors, although mutations were significantly more frequent in tumors of the distal colon. Mutations in the p53 gene did not correlate with mutations in the c-K-ras gene, indicating that colorectal cancer can develop through pathways independent not only of the presence of mutations in any of these genes but also of their cooperation.     

Similar incidence of K-ras mutations in lung carcinomas of FVB/N mice and FVB/N mice carrying a mutant p53 transgene

Mutated p53 genes are capable of complementing activated ras genes in the transformation of primary rat embryo fibroblasts in vitro. Mutations in both genes have also been found in several human cancers, including lung carcinomas. We generated transgenic mice containing a p53 construct with a missense mutation in exon 5 (ala135val) to study the role of p53 mutations in lung tumorigenesis, and to facilitate identification of other genetic events that might complement p53 mutations in mouse lung carcinogenesis. The p53 transgenic lines exhibited a higher frequency of lethal lung tumors than the parental FVB/N strain. We examined the spontaneously-arising lung carcinomas from mice expressing the mutated p53 transgene for K-ras mutations using single-stranded conformation polymorphism (SSCP) and/or direct sequencing approaches. Fifteen of 29 (52%) carcinomas contained mutations in the K-ras oncogene. Six of 15 of the K-ras mutations were in codon 61 and 9/15 were in codon 12. Subsequent analysis of spontaneous lung carcinomas from mice of the FVB/N parental strain showed that 9/12 (75%) carcinomas examined contained K-ras mutations. Two of these were in codon 12, one in codon 13, and 6 were in codon 61. These results demonstrate that the frequency of ras mutations does not differ between the p53 FVB/N transgenic mice and their parental FVB/N strain but suggest that a high frequency of mutations K-ras can be correlated with lung tumorigenesis in both groups of mice.      

Higher frequency of point mutations in the c-K-ras 2 gene in human colorectal adenomas with severe atypia than in carcinomas.

Human colorectal carcinomas may be induced from adenomas or they may occur de novo. To examine which is the main pathway, we analyzed point mutations at codon 12 in the c-K-ras 2 gene in 73 colorectal carcinomas, 13 metastatic tumors, 72 adenomas and 30 normal tissues. The c-K-ras 2 codon 12 mutation frequency was 0/30 in normal tissues, 0/17 in adenomas with mild atypia, 3/37 (8.1%) in adenomas with moderate atypia, 15/18 (83.3%) in adenomas with severe atypia, 19/73 (26.0%) in primary carcinomas and 3/13 (23.1%) in metastatic tumors. The mutation frequency in adenomas with severe atypia was much higher than that in carcinomas. These results indicate that many colorectal carcinomas may not be induced through adenomas with severe atypia.     

Absence of ST7 gene alterations in human cancer.

The ST7 gene was cloned and mapped to chromosome 7q31.1-q31.2, a region suspected of containing a tumor suppressor gene involved in a variety of human cancers. Subsequent investigation described the presence of ST7 mutations in human cell lines derived from breast tumors and primary colon carcinoma. Introduction of the ST7 cDNA into a prostate cancer-derived cell line abrogated in vivo tumorigenecity in nude mice. To clarify the role of the ST7 gene in cancer, we scrutinized primary head and neck squamous cell carcinomas, invasive ductal carcinomas of the breast, and adenocarcinomas of the colon. Loss of heterozygosity of D7S522/D7S677 was detected in 24% (4 of 17) of head and neck squamous cell carcinomas, 17% (2 of 12) of invasive ductal carcinomas of the breast, and 33% (8 of 24) of adenocarcinomas of the colon, but no somatic mutations were found in any of these specimens. We then searched for mutations in breast cancer cell lines and found a complete wild-type sequence in all, including cell lines previously reported to harbor mutations. We believe that the ST7 gene is not a primary target of inactivation in most human cancers with loss of heterozygosity at 7q31.1-q31.2.     

Direct sequencing analysis of exon 1 of the c-K-ras gene shows a low frequency of mutations in human pancreatic adenocarcinomas

We have applied direct dideoxy sequencing of DNA fragments amplified in vitro by the polymerase chain reaction to the detection of mutations in exon 1 of the c-K-ras gene in human pancreatic adenocarcinomas. Four fresh frozen primary tumors, one metastatic tumor, and twelve formalin-fixed paraffin embedded tumors were analysed. Only three cases showed a possible mutation in codon 12 in a small population of cells, in contrast to the high frequency reported for this alteration with the RNAase A protection assay and allele-specific oligoxynucleotide hybridization. No major difference in sensitivity was found between DNA sequence analysis, and the latter method. Our results suggest that if c-K-ras mutations are indeed present in pancreatic adenocarcinomas at the high frequency reported by others, they must be confined to a small fraction of the cell population to escape detection by direct sequencing. Such a phenomenon would have implications for c-K-ras mutations in the pathogenesis of pancreatic adenocarcinomas.     

Incidence of ras oncogene activation in lung carcinomas in Hong Kong.

BACKGROUND. In Hong Kong, lung carcinomas contribute to the majority of cancer deaths among Chinese. Point mutational activation of ras oncogenes has been observed in several populations. The incidence of these mutations in Hong Kong lung carcinomas was investigated. METHODS. Lung resections obtained from 52 Chinese patients whose conditions were newly diagnosed as non-small cell lung cancer, paraffin sections from 29 Chinese patients with previously diagnosed adenocarcinoma of the lung, and paraffin sections from 49 squamous cell carcinomas were examined for the presence of point mutations in Ki-ras codon 12, N-ras codon 61, and Ha-ras codon 12 oncogenes by allele-specific hybridization after specific amplification of appropriate regions of the DNA using the polymerase chain reaction. RESULTS. Among the 130 lung carcinomas investigated, Ki-ras point mutations were detected in seven cases, of which six were adenocarcinomas and one a squamous cell carcinoma. No mutations were detected in the N-ras and Ha-ras codons. CONCLUSIONS. The incidence of Ki-ras codon 12 point mutational activation in Chinese patients with adenocarcinomas was 6 of 63 (9.5%). The incidence of Ki-ras 12 point mutational activation among men with lung adenocarcinomas in Hong Kong (6 of 32 patients, 18.8%) is significantly different from that in women in Hong Kong (0 of 31 patients, 0%). Although ras oncogenes are implicated as having a role in the development of lung adenocarcinomas, especially among smokers, it is clear from these data that they are not associated with the unusually high incidence of lung adenocarcinomas among women in Hong Kong.     

Detection of activating mutations in the ras family genes in cytological specimens from lung-tumors

Mutations in the ras family genes (K-ras mainly) represent a common event in lung tumorigenesis which is frequently associated with poor clinical outcome. In order to investigate whether K-ras mutations are detectable in cytological material obtained from patients with lung cancer, 37 cytological specimens (16 fine needle aspiration and 21 bronchoscopy) were assessed for codon 12 point mutations in the H-, K- and N-ras genes by combined polymerase chain reaction-restriction fragment length polymorphism. K-ras codon 12 point mutations were found in 8 out of 37 (22%) specimens while no mutations were found in the H-ras and N-ras genes. Mutations were found in 27% (3 out of 11) of adenocarcinomas while in squamous cell carcinomas the incidence of mutations was 18% (3 out of 17). In addition, a K-ras codon 12 point mutation was found in one (12%) among 8 small cell carcinomas and in the only Hodgkin's lymphoma with metastasis in the lung. Our results are in agreement with previous results that recognise high incidence of K-ras activation in lung carcinomas, and indicate that detection of mutant ras alleles is possible in cytological material.     

High Frequency of Codon 12 but not Codon 13 and 61 K-ras Gene Mutations in Invasive Ductal Carcinoma of Breast in a South Indian Population

Background: Ras genes are thought to play an important role in human cancer since they have been foundto be activated frequently in several types of tumors including breast cancer, where the overall incidence ofK-RAS oncogene activation is 0-10%. Evaluation of K-RAS gene not only for mutational frequency but also formutation types in this downstream signaling gene pathway is necessary to determine the mechanisms of action.The present study was conducted to test the hypothesis that K-RAS activation is involved in breast cancer riskof south Indian population. Materials and Methods: A total of 70 paired pathologically confirmed tumor andnon-tumor tissues from the same breast cancer patients were analysed for most common K-RAS mutationsof codon 12,13 and 61 by polymerase chain reaction followed by restriction digestion and direct nucleotidesequencing method. Results: We found that a high rate of homozygous and heterozygous mutations of codon 12,but not codon 13 and 61, may influence the invasive ductal carcinoma of breast risk in this study. Conclusions:Our study indicated that only codon 12 may be involved in initiating breast carcinogenesis in India.     

Heterozygous ras mutations are preserved in serially passaged human tumor xenografts and established cell lines.

We examined c-K-ras gene point mutations in human tumor xenografts and established cell lines as markers of genetic stability. Our previous study demonstrated the stability of c-K-ras gene mutations in human primary neoplasms and their tumor xenografts through serial passages in mice. In this study, we established 27 human cell lines derived from various human tumor xenografts in nude mice. Point mutation of the c-K-ras gene at codon 12 was found in 29.6% (8/27) of the cell lines, as well as in 29.6% (8/27) of the xenografts. The eight ras-mutated cell lines were derived from corresponding tumor xenografts carrying the ras mutation. Heterozygous ras gene mutation was confirmed in seven of the eight ras-mutated cell lines, as well as their corresponding xenografts. The incidence, type and heterozygosity of the c-K-ras gene mutation showed no discrepancies between the original xenografts and the established cell lines. From these findings, we concluded that point mutation of the c-K-ras gene was very stable in human tumor xenografts and established cell lines derived from the xenografts.     

Mutational activation of c-Ha-ras gene in squamous cell carcinomas of rat Zymbal gland induced by carcinogenic heterocyclic amines

The activation of the c-Ha-ras gene and its carcinogen specificity were examined in squamous cell carcinomas (SCCs) induced by the mutagenic heterocyclic amines 2-amino-3-methylimidazo [4,5-f]quinoline (IQ),2-amino-3,8-dimethylimidazo[4,5-f]quinoxaline (MeIQx), and 2-amino-3,4-dimethylimidazo[4,5-f]quinoline (MeIQ) in the Zymbal gland in rats. DNA fragments of the c-Ha-ras gene were amplified from formalin-fixed and paraffin-embedded tissues by polymerase chain reaction and analyzed for activating mutations involving codons 12, 13, and 61 by oligonucleotide differential hybridization and sequencing. c-Ha-ras mutations were found in four of seven and two of six Zymbal gland SCCs induced by IQ and MeIQx, respectively. These mutations were located in either codon 13 or 61. In the case of MeIQ, point mutations at the second nucleotide of codon 13 were found in nine of the total 14 Zymbal gland SCCs and in one papilloma. Of the nine SCCs that had mutations in codon 13, two possessed mutations at the second nucleotide of codon 12 as well. Most reported mutations in c-Ha-ras are located at codon 12 or 61, but the heterocyclic amines in this study induced mutations not only at codons 12 and 61 but also in codon 13. Transversions were the dominant mutation induced by these heterocyclic amines.     

PIK3CA gene is frequently mutated in breast carcinomas and hepatocellular carcinomas

A recent report revealed that phosphoinositide-3-kinase, catalytic, alpha (PIK3CA) gene is somatically mutated in several types of human cancer, suggesting the mutated PIK3CA gene as an oncogene in human cancers. However, because the previous report focused the mutational search primarily on colon cancers, the data on PIK3CA mutations in other types of human cancers have been largely unknown. Here, we performed mutational analysis of the PIK3CA gene by polymerase chain reaction-single-strand conformation polymorphism assay in 668 cases of common human cancers, including hepatocellular carcinomas, acute leukemias, gastric carcinomas, breast carcinomas, and non-small-cell lung cancers. We detected PIK3CA somatic mutations in 26 of 73 hepatocellular carcinomas (35.6%), 25 of 93 breast carcinomas (26.9%), 12 of 185 gastric carcinomas (6.5%), one of 88 acute leukemias (1.1%), and three of 229 non-small-cell lung cancers (1.3%). Some of the PIK3CA mutations were detected in the early lesions of breast cancer carcinoma, hepatocellular carcinoma, and gastric carcinomas, suggesting that PIK3CA mutation may occur independent of stage of the tumors. The high incidence and wide distribution of PIK3CA gene mutation in the common human cancers suggest that alterations of lipid kinase pathway by PIK3CA mutations contribute to the development of human cancers.     

K-ras point mutation occurs in the early stage of carcinogenesis in lung cancer.

In order to determine the topographical distribution of the K-ras codon 12 mutations in carcinoma and preneoplastic lesions of the lung, selective ultraviolet radiation fractionation, as well as microdissection followed by polymerase chain reaction-restriction fragment length polymorphism (PCR-RELP), was performed. Fourteen of 61 samples amplified (23.0%) had a mutation in the K-ras codon 12. Of 41 adenocarcinoma, 12 samples (29.3%) had a mutation, whereas none of the squamous cell carcinomas had a mutation. One of six large-cell carcinomas, one of three carcinoid tumours and none of three other carcinomas had a mutation. Direct sequencing revealed that K-ras codon 12 of six samples were TGT (Cys), five samples were GTT (Val), two samples were GCT (Ala) and one sample was TTT (Phe). A total of 113 lesions of 13 cases covered by dot were amplified after UV radiation. All of 74 carcinoma lesions had the mutation, and intratumour heterogeneity was not observed. Of 39 non-malignant lesions, one type II cell hyperplasia had the mutation, which suggests that the K-ras mutation occurs in the early stage of carcinogenesis. The lack of intratumour heterogeneity supports the hypothesis.