K-ras activation and ras p21 expression in latent prostatic carcinoma in Japanese men.

Twenty-three clinically silent prostatic carcinomas discovered in Japanese men at autopsy were surveyed for ras proto-oncogene mutations by mutation-specific oligonucleotide probe hybridization after polymerase chain reaction (PCR) amplification from a section of formalin-fixed, paraffin-embedded tissue. Six of the 22 that were satisfactory amplified contained activating point mutations in codon 12 of K-ras, a significantly higher frequency than has been reported in patients with clinically advanced disease in the United States. Of the six cases with activating point mutations in codon 12 of K-ras, one had a GGT----GAT transition, four had GGT----GTT transversions, and one had both GGT----GAT and GGT----GTT mutations. Sections from the same tissues were immunohistochemically stained with an anti-ras p21 antibody. Carcinoma cells stained for ras p21 to some degree in 13 cases. Immunohistochemically detectable expression of p21 was always focal and was not necessarily associated with K-ras mutation. K-ras oncogene activation in prostatic carcinoma appears to merit additional study as a significant event in the pathogenesis of this neoplasm.     

K-ras activation in neoplasms of the human female reproductive tract

The role of cellular oncogenes in the development of epithelial tumors of the human female reproductive tract has not previously been extensively studied. DNAs isolated from ten human uterine, 13 ovarian, and four cervical neoplasms and from three cell lines derived from endometrial adenocarcinoma were investigated by dot blot hybridization after polymerase chain reaction amplification of ras gene sequences and in some cases by NIH 3T3 transfection. Transforming activity was found in two of nine endometrial adenocarcinomas, but none of seven ovarian carcinomas and none of four cervical carcinomas showed transforming activity. K-ras sequences with a GGT----GAT mutation in codon 12 were demonstrated in both transformants derived from endometrial carcinoma. K-ras codon 12 mutations were similarly detected in six of 13 endometrial carcinomas (one GAT and GCT, one GTT and GCT, two GAT, two GTT) and two of 13 ovarian tumors (GAT and GCT, GAT), both mucinous adenocarcinomas. Point mutation of K-ras in codon 12 is thus comparably frequent in uterine endometrial carcinomas and in colorectal carcinomas and may have similar significance as an event that contributes to progression of these tumors. Cervical carcinomas and ovarian tumors in general, with the possible exception of mucinous adenocarcinoma of the ovary, do not appear to have this characteristic.     

Clinical implications of K-ras mutations in malignant epithelial tumors of the endometrium.

Tumorigenesis in humans and experimental animals appears to involve the activation of ras protooncogenes for a number of organ systems and seems to be important to the development of the metastatic phenotype in several model systems. Clinically, the presence of activated ras protooncogenes has been reported to be a negative prognostic factor in the myelodysplastic syndrome and in adenocarcinoma of the lung. In the present study we examined 49 cases of endometrial carcinoma for mutations in the first exon of K-ras using the polymerase chain reaction and direct sequencing. Mutations in codon 12 or 13 of K-ras were detected in 6 of 49 cases (12.2%). These six cases consisted of five endometrioid endometrial carcinomas, each of which had a mutation in codon 12, and one case of clear cell carcinoma, which had a mutation in codon 13. In our study the presence of mutations in K-ras appeared to be an unfavorable prognostic factor. Three of six patients with the mutation died during follow-up, while only 7% of the 43 patients without K-ras mutations expired during this same period. In multivariate analysis using the Cox proportional hazard model, K-ras activation appeared to be an independent risk factor when compared with clinical stage, depth of myometrial invasion, and patient age. Thus, our findings support the hypothesis that K-ras protooncogene activation plays an important role in determining the aggressiveness of endometrial carcinoma.     

Detection of K-ras mutations in pancreatic and hepatic neoplasms by non-isotopic mismatched polymerase chain reaction.

Mutations within codon 12 leading to activation of Kirsten-ras (K-ras) genes occur in a wide variety of human tumors, but have been reported most frequently in pancreatic carcinomas. We studied twenty-four paraffin-embedded pancreatic and hepatic tumors and two colon carcinoma cell lines with a rapid and simple approach that exploits allele-specific amplification of genomic DNA in a polymerase chain reaction (PCR). We extend the utility of this technique, which is dependent on an exact match at the 3' nucleotide between synthetic oligonucleotides and template DNA, to analyse paraffin-embedded tumor samples for the presence of point mutations at the first and second base of codon 12 of the K-ras gene. The PCR mismatch amplification technique demonstrated a 66% incidence of K-ras mutations at codon 12 in the group of pancreatic neoplasms as a whole. The percentage of mutations varied only slightly in the pancreatic cancer subcategories: 75% in ampullary, 66% in bile duct and 57% in the ductal adenocarcinomas. One islet cell carcinoma and normal tissues adjacent to the tumors revealed wild-type alleles only. One hepatoblastoma and one of six hepatocellular carcinomas also had codon 12 mutations. The PCR mismatch is a sensitive and rapid method that may be useful in screening neoplasms for K-ras point mutation and can be applied to archival material. This application allows a retrospective analyses of a wide range of pathological specimens to determine the role of K-ras mutations in human tumorigenesis.     

The balanced induction of K-ras codon 12 and 13 mutations in mucosa differs from their ratio in neoplastic tissues

The aim of this study was to compare the ratio of K-ras codon 12 and 13 mutations in various tissues of colorectal cancer patients. Multiple samples of inconspicuous mucosa and a sample of carcinoma tissue were taken from 36 colorectal cancer patients (group I) and these results were compared with those from polyp and carcinoma tissues of another 48 colorectal cancer patients (group II). A polymerase chain reaction-restriction fragment length polymorphism (PCR-RFLP) assay was used to detect the respective point mutations. The results of this assay were complemented by sequencing the K-ras mutations. In mucosa tissue, the ratio of codon 12 and 13 mutations was nearly equal (0.9:1) whereas the respective ratio in tumour tissue showed a strong preponderance of K-ras codon 12 mutations (14:1, p=0.004). In polyp tissue of patients from group II, the ratio was 2.7:1 and that in carcinomas was 19:1 (p=0.053). The prevalence of both types of mutation was 14.6% in all mucosa samples, corresponding to 30.6% of group I patients. The K-ras mutation rate in carcinoma tissue of the same patients was 38.9%. Similarly, 33.4% of all polyp and 41.7% of all carcinoma samples from group II harboured K-ras codon 12 and/or 13 mutations. Sequencing confirmed 59 of 60 K-ras codon 12 mutations, but due to the detection limit for sequencing (1:10(4)) only 10 of 20 K-ras codon 13 mutations were confirmed. It is concluded that after balanced induction K-ras codon 12 mutations increase in frequency relative to K-ras codon 13 mutations during tumour progression.     

Association of K-ras mutations with liver metastases from colorectal carcinoma

BACKGROUND: Colorectal carcinomas were studied regarding early proof of liver metastases through determination of K-ras mutations. PATIENTS AND METHODS: Seventy-seven colorectal carcinomas were investigated for the presence of point mutations in codon 12 and 13 of the K-ras gene, using single-strand conformation polymorphism (SSCP) analysis and direct sequencing. RESULTS: Twenty-six carcinomas were positive for K-ras mutations, of which 21 had codon 12 and 5 had codon 13 mutations. Twenty patients with K-ras-positive tumor (20 out of 26: 77%) developed liver metastases, of which 13 had simultaneous metastases and 7 had metachronous metastases. There was a significant association between K-ras mutations and liver metastases (p=0.03). A multivariate logistic regression model demonstrated that the involvement of lymph node (p<0.01) and K-ras mutations (p=0.02) were predictive factors for liver metastases from colorectal carcinoma. Sequencing in carcinomas without liver metastases showed the base change in the first position of codon 12, whereas with liver metastases it showed significantly frequent base change in the second position of codon 12 (p<0.01). CONCLUSION: It is suggested that the presence of K-ras mutation, especially base change in the second position of codon 12, may predict liver metastases from colorectal carcinoma.     

Disseminated colorectal tumor cells in organs prone to metastasis detected by new double enriched nested-PCR in comparison with recognized assays

Hypothetically, K-ras mutations can be used as a marker of disseminated tumor cells (DTCs) in patients with K-ras mutated primary carcinoma. This study focused on the development of a useful assay for detecting low numbers of DTCs in potential target tissues of metastatic K-ras codon 12 mutated colorectal cancer. Tumor, liver, lymph node and bone marrow tissues from 46 colorectal carcinoma patients were examined for K-ras codon 12 mutations with a new double enriched nested (DEN)-PCR and the incidence of mutations was compared to those obtained from three established assays. DEN-PCR followed by sequencing found one mutated cell within 107 K-ras codon 12 wild-type cells and was more sensitive than other methods (1:106-1:102). Colon carcinomas (26/46) and adenomas (1/3) harbored mutations in K-ras codon 12. Sixteen of these 27 mutated tumors were found with all assays, two with three methods and one with the two most sensitive assays. In 8 cases, only DEN-PCR identified the K-ras mutation, and thus prevailed over the other methods used (p<0.002). Eight of 26 patients with K-ras mutated colorectal carcinoma also harbored K-ras mutated DTCs in liver and lymph nodes, respectively, and 4 in bone marrow. For liver and lymph node samples, DTC-mutations were identical to those in the primary carcinoma but those in bone marrow differed from the respective mutation in the primary carcinoma. In conclusion, DEN-PCR is a highly sensitive method for detecting K-ras mutations as marker of early and late tumor cell dissemination in tissues potentially harboring colorectal carcinoma metastases.     

K-ras codon 12 and 13 mutations are correlated with differential patterns of tumor cell dissemination in colorectal cancer patients

The aim of this prospective study was to relate the incidences of cytokeratin 20 (CK20) and guanylylcyclase C (GCC) in lymph node, liver, and bone marrow specimens of 245 colorectal cancer (CRC) patients with the K-ras oncogene status of the corresponding primary tumor. Qualitative RT-PCR detection of CK20 and GCC mRNA was used as marker of circulating epithelial cells (CEC). Samples were considered positive for CEC only when both markers were detected concomitantly. For the detection of K-ras mutations, a PCR-RFLP assay was used. In the group with K-ras mutated primary carcinomas (n=92), CEC were detected in 62% of lymph node-, 43% of liver-, and 2% of bone marrow samples. No statistical significance was found when comparing these results with those from patients with K-ras wild-type carcinoma (59%, 46%, and 0%, respectively). In contrast to this combined evaluation, separate analysis of K-ras codons 12 (n=75, 82%) and 13 (n=17, 18%) revealed significantly differing CEC incidences. Lymph node specimens from corresponding K-ras codon 13 mutated carcinomas showed a significantly higher CEC incidence (82%) than the groups with codon 12 mutation (57%, p<0.05) or K-ras wild-type sequence (59%, p<0.05). Unlike these findings in lymph nodes, liver biopsies from corresponding carcinomas with K-ras codon 12 mutation or wild-type sequence were significantly more often positive for CEC (31% and 29%) than specimens from K-ras codon 13 mutated primary CRC (12%, p<0.04, respectively). In conclusion, colorectal carcinomas with K-ras codon 12 mutation showed the same pattern of tumor cell dissemination as their K-ras wild-type counterparts. Since K-ras codon 12 mutations prevailed 4-fold over codon 13 mutations, combined analysis of the two codons showed the same result. However, sub-analysis of patients with K-ras codon 13 mutation revealed that the respective CEC incidence was significantly increased in lymph nodes, but decreased in liver biopsies.     

Microsatellite instability and K-ras mutations in gastric adenomas, with reference to associated gastric cancers.

Gastric adenomas are often detected in the stomach resected for gastric cancer. Previous investigation have revealed that the prevalence of their malignant transformation is generally low, but the frequent coexistence with carcinoma suggests that they may share some common processes with gastric cancer in tumorigenesis. In contrast to the cumulative information about genetic alterations in gastric cancer, inquiries into the genetic changes of adenoma and coexisting carcinoma in the same individual's stomach are still few. We investigated microsatellite instability (MSI) and K-ras point mutations in codons 12 and 13 in 50 lesions of gastric adenomas in 43 cases, and 31 lesions of gastric cancers that coexisted with these adenomas. In gastric adenomas, we found seven lesions (14.0%) to have microsatellite instability (MSI) at one or more loci, and most of them (six cases) had MSI at only one locus and were not associated with alterations in presumable target molecules. MSI was detected more frequently (11/31, 35.5%) and more extensively (five lesions at multiple loci) in accompanying gastric carcinomas. The prevalence of MSI in adenomas was more frequently found in those with synchronous gastric cancer (6/37, 16.2%, vs. 1/13, 7.6%) than without, and gastric adenoma accompanied by gastric cancer with multiple MSI tended to have MSI more frequently than that accompanied by cancer without MSI (4/5, 80%, vs. 1/24, 4.2%; p = 0. 01). In at least some individuals, MSI appears to represent one step in the pathway of gastric tumorigenesis, shared by adenoma and carcinoma. We found K-ras gene alteration in 8 lesions (16.0%) out of 50 gastric flat adenomas and no difference in its prevalence between adenoma with or without cancer. Only one gastric cancer, which had adenoma without K-ras mutation, had K-ras codon 12 mutation. Adenomas with a higher grade of atypia (p < 0.05) more frequently carried K-ras point mutation, which is consistent with the situation in colorectal adenoma. We conclude that MSI, not K-ras mutation, is a shared genetic alteration in adenoma and carcinoma of the individual stomach.     

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.     

The K-ras mutation pattern in pancreatic ductal adenocarcinoma usually is identical to that in associated normal, hyperplastic, and metaplastic ductal epithelium

BACKGROUND: Hyperplastic ductal lesions of the pancreas are believed to represent precursors of ductal adenocarcinoma. The most frequent mutation in manifest ductal carcinoma of the pancreas is the K-ras mutation at codon 12. The frequency and significance of this mutation in precursor lesions are a matter of controversy. METHODS: The study included 35 resection specimens of ductal adenocarcinoma of the head of the pancreas and 3 noncancerous, noninflammatory pancreases. Ductal lesions were classified according to established criteria. Single cells from these lesions were microdissected and analyzed by the denaturing gradient gel electrophoresis polymerase chain reaction method. RESULTS: All primary adenocarcinomas showed a K-ras mutation at codon 12 (25 cases with GAT, 7 cases with GTT, and 3 cases with CGT). One hundred and six of 364 ductal lesions were positive for the mutation. The highest relative percentage (53%) occurred in adenomatoid hyperplasia, followed by 36% in papillary hyperplasia, 26% in mucinous hypertrophy, and 14% in squamous metaplasia. With only two exceptions the mutation pattern of the ductal lesions and that of the corresponding primary tumor were identical. Twenty-one samples from normal ducts (17%) also harbored the K-ras mutation, as did 3 lesions from noncancerous specimens. CONCLUSIONS: K-ras mutations are common events in normal, hyperplastic, metaplastic, and neoplastic pancreatic ductal cells. Because K-ras mutations frequently, although not exclusively, are related to mucinous differentiation of pancreatic cells, this mutation may not cause but only promote mucinous differentiation. The prevalence of a certain mutation pattern in nonneoplastic and neoplastic ductal cells in an individual pancreas suggests the dominance of one carcinogenic factor.     

Sensitive detection of K-ras mutations augments diagnosis of colorectal cancer metastases in the liver.

Postoperative survival of colorectal cancer patients is often delineated by metastases spreading to the liver. Current clinical diagnostic procedures are unable to discover micrometastases in this organ. Our aim was to develop a diagnostic tool for detecting micrometastases that are present at the time of surgery. Therefore, a PCR-RFLP assay was set up tracking point mutations of the K-ras oncogene at codons 12 and 13, based on mismatch primers and restriction enzymes BstXI and XcmI. The detection limit of this assay was one mutant in one million wild-type cells. One hundred forty-two patients with colorectal carcinoma were screened for these mutations in tissue samples from their tumor, proximally adjacent mucosa, and liver. Of these, 67 patients (46%) were positive for a K-ras mutation, of which 58 had codon 12 and 9 had codon 13 mutations. No patient without a K-ras-positive tumor showed a mutation in mucosa, but 11 patients with a K-ras-positive tumor (11 of 58; 19%) were found to bear a K-ras mutation in their mucosa, and in 21 patients (21 of 64; 33%), a K-ras mutation was detected in liver tissue. Sequencing of all mutated samples revealed a 92% confirmation of PCR-RFLP results. In summary, the assay is a useful tool for detecting K-ras codon 12 and 13 mutations and allows early proof of molecular determinants of liver metastases. Such knowledge will improve the staging of colorectal cancer patients and could beneficially influence their prognosis if followed by an effective therapy.     

K-ras activation in colorectal tumors from patients with familial polyposis coli

K-ras gene mutation in colorectal tumors from patients with familial polyposis coli were investigated using oligonucleotide probes specific for a mutation at codon 12, 13, or 61 of the K-ras gene. The authors examined 22 colorectal carcinomas and 51 colorectal adenomas from 41 familial polyposis coli patients and observed mutations at codons 12 and 13 in eight of 22 colorectal carcinomas (36%) and six of 51 colorectal adenomas (12%). Thus, the frequency and sites of K-ras gene mutation in colorectal carcinoma from familial polyposis coli patients are similar to those in cases of sporadic colorectal carcinoma and may not be the first genetic event linked to the tumorigenesis.     

Specific codon 13 K-ras mutations are predictive of clinical outcome in colorectal cancer patients, whereas codon 12 K-ras mutations are associated with mucinous histotype.

BACKGROUND: K-ras mutations, one of the earliest events observed in colorectal carcinogenesis, are mostly found in codons 12 and 13, and less frequently in codon 61, all three of which are estimated to be critical for the biological activity of the protein. Nevertheless the prognostic significance of such mutations remains controversial. Our purpose was to assess whether any or specific K-ras mutations in primary colorectal cancer had prognostic significance and were linked to clinico-pathological parameters. PATIENTS AND METHODS: Paired tumor and normal tissue samples from a consecutive series of 160 untreated patients (median of follow up 71 months), undergoing resective surgery for primary colorectal carcinoma, were prospectively studied for K-ras mutations by PCR/single strand conformation polymorphism sequencing. RESULTS: Seventy-four of the 160 (46%) primary colorectal carcinomas presented mutations in K-ras: 54% in codon 12, 42% in codon 13 (particularly G-->A transition) and 4% in both. Codon 12 K-ras mutations were associated with mucinous histotype (P <0.01), while codon 13 K-ras mutations were associated with advanced Dukes' stage (P <0.05), lymph-node metastasis (P <0.05) and high S-phase fraction (P <0.05). Multivariate analysis showed that codon 13 K-ras mutations, but not any mutation, were independently related to risk of relapse or death. CONCLUSIONS: Our results suggest that codon 12 K-ras mutations may have a role in the mucinous differentiation pathway, while codon 13 mutations have biological relevance in terms of colorectal cancer clinical outcome.     

K-ras activation in non-small cell lung cancer in the dog.

To investigate the role of K-ras mutations in canine non-small cell lung cancer, we first determined the nucleotide sequence of the normal canine K-ras gene and then examined 21 canine lung tumors for activating K-ras mutations. Canine K-ras was analyzed by direct sequencing of polymerase chain reaction products generated with oligonucleotide primers derived from the human K-ras sequence. Four nucleotide differences were found between the canine and human K-ras sequence from position 5 to 211. The deduced amino acid sequence of the canine gene was identical to that of the human. Activated K-ras alleles were detected in 5 of the 21 canine lung tumors examined. The activating lesions were point mutations, predominantly in codon 12. Of the 14 adenocarcinomas examined, 2 (14%) had K-ras mutations. Two of 5 (40%) adenosquamous carcinomas and the only large cell carcinoma also contained activated alleles. The overall frequency of K-ras point mutation in non-small cell lung cancer (25%) is similar to that reported in human non-small cell lung cancer. We conclude that K-ras activation by point mutation is associated with, but not necessary for, non-small cell lung cancer development in the dog.     

K-ras activation in premalignant and malignant epithelial lesions of the human uterus

We previously reported (Cancer Res., 50:6139-6145, 1990) a significant frequency of activating point mutations in codon 12 of the K-ras oncogene in endometrial adenocarcinomas of the uterine corpus (series 1). To further define the role of ras activation in the development of endometrial adenocarcinoma, we surveyed cystic, adenomatous, and atypical hyperplasias of uterine endometrium and additional cases of endometrial and cervical carcinoma (series 2) for the presence of activating mutations in cellular protooncogenes of the ras family. Polymerase chain reaction was performed from deparaffinized sections of formalin-fixed paraffin-embedded tissue. We screened for point mutations in codons 12, 13, and 61 of the K-, H-, and N-ras genes by dot blot hybridization analysis with mutation-specific oligomers. Mutations in K-ras were also confirmed by direct genomic DNA sequencing. Of 19 endometrial adenocarcinomas in series 2, point mutations in ras genes were found in 7 tumors. Six contained single-base substitutions, five in codon 12 of K-ras and one in codon 12 of N-ras. The seventh tumor contained two different point mutations in codon 12 of K-ras. In one endometrial adenocarcinoma, tumor cells with point mutations in K-ras were predominantly localized to a portion that had a more aggressive histological pattern. In endometrial hyperplasia, K-ras mutations, one in codon 12 and one in codon 13, were found in 2 of 16 hyperplasias histologically classified as atypical and clinically considered premalignant. None of 6 adenomatous hyperplasias and none of 12 cystic hyperplasias, the latter of which is considered clinically benign, contained any detectable ras mutations. No mutations in H-ras were detected in either carcinomas or hyperplastic tissue.     

Analysis of the K-ras/B-raf/Erk signal cascade, p53 and CMAP as markers for tumor progression in colorectal cancer patients

Colorectal cancer patients may succumb to their disease because of local recurrence or formation of metastasis. To develop a prognostic tool for these fatal types of progression, 23 patients with colorectal carcinoma were included in this study for the detection at the time of surgery of the incidence of K-ras, B-raf and p53 mutations, the phosphorylation status of Erk and the expression of cystatin-like metastasis-associated protein (CMAP) in tumor, mucosa and liver samples. Polymerase chain reaction-restriction fragment length polymorphism and PCR-SSCP were used to detect the respective mutations. The results of these assays were complemented by sequencing the K-ras, B-raf and p53 mutations. A multiplex RT-PCR assay was used to detect the CMAP mRNA levels and the phosphorylation status of Erk in tumor samples was assessed by Western blot using a phosphospecific Erk antibody. The carcinomas were classified as stages T4 (70%), T3 (17%), T2 (9%) and T1 (4%) and thus represent a group of advanced colorectal carcinomas. The carcinomas (8 out of 23, 39.1%) were mutated in K-ras codons 12 or 13 and two patients had a B-raf (V599) mutation in their tumor. Of 22 tumors, 11 (50%) were positive for pErk, indicating the activation of the RAS/RAF/ERK signaling pathway. Of the 23 tumors, 13 (65.5%) showed an increased CMAP RNA level. Notably, 10 of these 13 patients have already died and two developed liver metastasis. Mutations in p53 were found in only 6 patients (26%), with 6 being detected in carcinoma, 1 in mucosa and 1 in liver tissue. These alterations were classified as non-sense (n=1), mis-sense (n=2) and frame-shift mutations (n=1) as well as intron polymorphisms (n=5). There was a significant correlation between Erk activation and K-ras codon 12 mutation (p=0.016), but not between K-ras codon 13 or B-raf mutations and Erk activation. Furthermore, there was a significant correlation of each positive marker with tumor stage (p=0.001).     

K-ras mutation is an early event in pancreatic duct carcinogenesis in the Syrian golden hamster.

K-ras oncogene mutation has been shown to be a frequent event in pancreatic ductal adenocarcinomas induced by the carcinogen N-nitroso-bis(2-oxopropyl)amine in the hamster. The present study examines the mutational status of the K-ras oncogene in lesions that precede the appearance of invasive ductal adenocarcinomas. Syrian golden hamsters (80-100 g) received 12 weekly doses of 15 mg/kg N-nitroso-bis(2-oxopropyl)amine and were serially sacrificed at 8, 12, 14, 16, or 24 weeks following the initiation of treatment. Ten microns-thick sections of formalin-fixed paraffin-embedded pancreas were examined for hyperplasia, papillary hyperplasia, carcinoma in situ, and invasive and metastatic ductal carcinoma. Marked lesions of interest were scraped from the slide, subjected to polymerase chain reaction-mediated amplification of the first exon of the K-ras gene, and probed by oligonucleotide-specific hybridization for mutations at codon either 12 or 13. Of 186 samples assayed, K-ras codon 12 mutations were detected in 26% of hyperplasias, 46% of papillary hyperplasias, 76% of carcinoma in situ, 80% of adenocarcinomas, and 43% of lymph node metastases. Codon 12 mutations were exclusively G to A changes at the second position. Codon 13 mutations were only detected in 9 of 168 samples. These results suggest that K-ras activation is an early event in N-nitroso-bis(2-oxopropyl)amine-induced pancreatic carcinogenesis in the hamster.     

癌基因K-ras、C-myc、erbB-2的激活与非小细胞肺癌组织学类型相关性研究

为探讨癌基因突变、扩增与非小细胞肺癌发生及类型间的关系，应用核酸杂交的方法检测了63伤1肺手术标本中（腺癌19例，鳞癌23例，腺鳞癌3例，大细胞癌3例，小细胞癌3例，其它12例）三种癌基因（c－myc、K－ras、erbB－2）的扩增及突变。实验结果显示：50％（24／48）的非小细胞癌分别出现三种癌基因的激活；31．6％（6／19）的腺癌出现K－ras12密码子突变及K－ras扩增；30．4％（7／23）的鳞癌有erbB－2扩增；10．4％（5／48）的非小细胞癌存在c－myc扩增。提示K－ras突变可能为肺腺癌所特有，而erbB－2扩增是肺鳞癌发生的重要因素。     

Rapid detection of ras oncogenes in human tumors: applications to colon, esophageal, and gastric cancer

We have developed a rapid, nonradioactive large scale method for the detection of ras oncogenes in human tumors. DNA is amplified by the polymerase chain reaction (PCR), and then digested with specific restriction enzymes to detect either endogenous or primer-mediated Restriction Fragment Length Polymorphisms (RFLPs). We report here that three of 15 colon tumors tested contain K-ras codon 12 aspartic acid mutations and one, along with the HCT 116 colon carcinoma cell line, contains a K-ras codon 13 aspartic acid mutation. On the other hand, we did not detect H- or K-ras codon 12 mutations or the K-ras codon 13 aspartic acid mutation in 25 esophageal and 27 gastric cardia tumors isolated from patients in Lin-xing County, China. By incorporating nucleotide substitutions in PCR primers, this method can be applied towards the rapid, non-radioactive screening of virtually any genetic disease caused by known point mutations.