Role of glutathione, glutathione S-transferases and multidrug resistance-related proteins in cisplatin sensitivity of head and neck cancer cell lines

Spontaneous proliferative liver lesions were found in 15 (13 males and 2 females) of 244 (122 of each sex) transgenic (Tg) mice carrying the human prototype c-H-ras gene (rasH2). The liver lesions included 3 foci of cellular alteration, 1 hepatocellular adenoma, 5 hepatocellular carcinomas, and 4 hepatic hemangiosarcomas in the males and 1 focus of cellular alteration and 1 hepatocellular carcinoma in the females. The mutation patterns of the human and endogenous mouse c-H-ras codon 61 in these proliferative liver lesions were analyzed by DNA amplification using polymerase chain reaction, single-strand conformation polymorphism (PCR-SSCP), and oligonucleotide dot blot hybridization. The hepatocellular carcinomas in 4 males and 1 female contained a point mutation in the mouse c-H-ras gene: 3, 1, and 1 carcinomas had a CAA to AAA transversion at the first base of codon 61, a CAA to CTA transversions, and a CAA to CGA transition at the second base of codon 61, respectively. No point mutations in the human c-H-ras transgene were detected in any hepatocellular carcinoma. All 4 hepatic hemangiosarcomas had a CAG to CTG transversion at codon 61 of the human c-H-ras gene, but no point mutations were detected in codon 61 of the mouse c-H-ras gene. No mutations in human or mouse c-H-ras codon 61 were detected in altered cell foci or hepatocellular adenoma. These results indicate that spontaneous liver tumors in rasH2 Tg mice contain different mutation patterns depending on the histologic type or cell origin of the tumors (i.e., hepatocellular carcinomas or hepatic hemangiosacomas). The absence of similar mutations in foci of cellular alteration and the hepatocellular adenoma suggests that the occurrence of codon 61 point mutations is a late event in the progression of hepatocellular neoplasia in rasH2 Tg mice.     

Mutations of K-ras oncogene and absence of H-ras mutations in squamous cell carcinomas of the lung

Mutations of the K-ras gene have been implicated in the pathogenesis of human lung adenocarcinomas. In most studies published so far, squamous cell lung cancers harbored ras mutations only exceptionally or no mutations were detected at all. We have examined 141 lung tumor DNA samples for mutations in codons 12, 13, and 61 of K-ras and H-ras oncogenes. A large panel of 118 squamous cell carcinomas was included in the study. For K-ras codon 12, we used a sensitive two-step PCR-restriction fragment length polymorphism method which detects <1% of mutated DNA in the sample. K-ras mutations were found in 17 tumors (12%; 14 in codon 12 and 3 in codon 13). Among 19 adenocarcinomas, mutation was revealed in 7 samples (37%). Of these, one sample harbored two point mutations in codon 12. Nine mutational events were found in squamous cell carcinomas (8%, one adenosquamous carcinoma included, all in codon 12). Of four large cell carcinomas, one contained a mutation. Mutant-enriched PCR products harboring mutations were directly sequenced. Fifteen mutational events were G-->T transversions or G-->A transitions, one was a G-->C transition, and one sample revealed a frameshift deletion of one G from codon 12. Similar mutational spectrum was found in both squamous cell carcinomas and adenocarcinomas, suggesting similar carcinogenic pathways in both histological types of the tumor. The presence of mutations did not correlate with the stage of the disease. Moreover, we analyzed all samples for mutations in codons 12, 13, and 61 of the H-ras gene. We found only one mutation in codon 12. Thus, H-ras mutations apparently play an inferior role in lung carcinogenesis. We conclude that mutations of the K-ras oncogene can play a role in the development of not only lung adenocarcinomas but also of a subset (about 8%) of squamous cell carcinomas.     

Ha-ras mutations in N-nitrosomorpholine-induced lesions and inhibition of hepatocarcinogenesis by antisense sequences in rat liver

To evaluate the application of Ha-ras mRNA antisense oligonucleotide therapy for liver tumors, we examined the frequency and types of mutation in codon 61 of the Ha-ras oncogene in preneoplastic lesions and hepatocellular carcinomas induced by N-nitrosomorpholine (NNM) in rats. Thirty-seven percent of preneoplastic lesions and 50% of hepatocellular carcinomas contained mutations, mostly CAA-CTA and CAA-AAA transversions. We also investigated the effects on NNM-induced lesions of an antisense oligonucleotide directed against a point mutation (CAA-CTA) in codon 61 of Ha-ras mRNA. In this experiment, Sprague-Dawley rats were given free access to water containing NNM for 8 weeks and received twice-weekly i.p. injections of a mutated Ha-ras antisense oligonucleotide with a 5' phosphorothioate linkage or a sense oligonucleotide in oligonucleotide-liposome complexes. At week 16, rats that had received the mutated Ha-ras antisense oligonucleotides had significantly fewer and smaller preneoplastic lesions positive for glutathione-S-transferase, placental type, and had smaller hepatocellular carcinomas than rats that had received the sense oligonucleotide. Mean cellular fluorescence in the liver was found to increase with higher doses of mutated, fluorescein-isothiocyanate-labeled antisense or sense oligonucleotides. Moreover, mutated Ha-ras antisense oligonucleotide decreased the expression of mutated Ha-ras mRNA (CAA-CTA). Our findings indicate that mutated Ha-ras antisense oligonucleotide significantly inhibits hepatocarcinogenesis in rats and could be an effective therapy against liver tumors.     

Rapid detection of K-ras gene mutations in canine lung cancer using single-strand conformational polymorphism analysis

A total of 126 spontaneous lung tumors from pet dogs were examined for K-ras mutations within exon 1 and exon 2 using a non-radioisotope single-strand conformational polymorphism analysis (SSCP) detection method on PCR products. Mutations were confirmed by direct DNA sequencing. Tumors were classified as adenomas (9), bronchioloalveolar carcinomas (59), adenocarcinomas (30), adenosquamous carcinomas (16), squamous cell carcinomas (3) and anaplastic carcinomas (9). Nineteen mutations were detected in the malignant tumors: 18 occurred in exon 1 codon 12 and one in exon 2 codon 61. No mutations were present in the adenomas. The most common mutation was a G-->A transition (11/19) in the second position of codon 12. Based on this study, K-ras mutations occur in canine non-small cell lung carcinomas. The frequency and type of mutation more closely matches tumors from human non-smokers with K-ras mutations than smokers. With the application of screening techniques such as SSCP, large numbers of dog tumors can be examined to provide a large animal model for comparative studies of carcinogenesis.     

Detection of dibenzo[a,l]pyrene-induced H-ras codon 61 mutant genes in preneoplastic SENCAR mouse skin using a new PCR-RFLP method

One of the key events in tumor initiation in mouse skin is mutational activation of the H-ras gene. Papillomas induced by the most carcinogenic environmental polycyclic aromatic hydrocarbon (PAH), dibenzo[a,l]pyrene (DB[a,l]P), in SENCAR mouse skin contain a specific H-ras codon 61 (CAA-->CTA) mutation. We describe here detection of these mutations in preneoplastic skin by measuring the frequency of an induced XbaI RFLP, created by the mutation. Development of the PCR-XbaI RFLP method, sensitive enough to detect 1 codon 61 mutant allele among 10,000 wild-type genes, is described. The results indicate that codon 61 mutations are induced 1 day (0.1%) after DB[a,l]P treatment on mouse skin, reach a high value (5%) by day 3, rapidly decline between days 7-9 and increase again during the clonal expansion of pre-papillomas into tumors. The detection of codon 61 mutations 1 day after DB[a,l]P exposure suggests that mutations occurred by pre-replication misrepair.     

Detection of K-ras mutations in lung carcinomas: relationship to prognosis

The K-ras mutation is one of the most common genetic alterations found in human lung cancer. To evaluate the prognostic value of ras gene alterations in lung cancer in a U.S. population, we have screened 173 human lung tumors, which included 127 adenocarcinomas, 37 squamous carcinomas, and 9 adenosquamous carcinomas, for mutations in the K-ras gene using the combination of the PCR and denaturing gradient gel electrophoresis. Forty-three tumors contained K-ras mutations. Of these, 41 were identified among the adenocarcinomas (32%), 1 among the squamous carcinomas (2.7%), and 1 among the adenosquamous carcinomas (11%). Forty of these mutations were found in codon 12 and consisted of 24 G to T transversions, 12 G to A transitions, 2 G to C transversions, and 1 double GG to TT mutation. Two other G to T transversions were found in codon 13, and 1 A to C transversion was found in codon 61. The data showed that gender did not seem to affect the incidence and the types of the K-ras mutations or amino acid changes. Examination of the mutations in adenocarcinomas in relation to overall survival showed no difference in adenocarcinomas with K-ras mutations compared with K-ras-negative adenocarcinomas. However, the substitution of the wild-type GGT (glycine) at codon 12 with a GTT (valine) or a CGT (arginine) showed a strong trend (P = 0.07) toward a poorer prognosis compared with wild-type or other amino acid substitutions. Substitution of the wild-type glycine for aspartate (GAT) showed a strong trend (P = 0.06) for a better outcome than the valine or arginine substitution. Although these trends will require larger patient populations for verification, these data suggest that the prognostic significance of K-ras mutations may depend on the amino acid substitution in the p21(ras) protein.     

Detection and clinical correlations of ras gene mutations in human ovarian tumors

In epithelial ovarian neoplasms K-ras codon 12 gene mutations show a wide variation fluctuating between 4-39% in invasive carcinomas and 20-48% in borderline malignant tumors. In this study, we showed the pattern of point mutations in codon 12 of the K-ras, H-ras and N-ras genes, using polymerase chain reaction restriction fragment length polymorphism analysis in 74 tissue specimens of Greek patients with epithelial ovarian tumors. K-ras and H-ras gene mutations were detected in 11/48 (23%) and 3/48 (6%) cases with primary invasive ovarian carcinomas, respectively, while N-ras gene mutations were not found. No mutation of K-, H- and N-ras genes was detected in 23 ovarian cystadenomas. In 1 out of 3 borderline ovarian tumors (33%) we found an H-ras gene mutation. The prevalence of mutations in K-ras gene was 1/8 (13%) in mucinous, 7/29 (24%) in serous, 1/3 (33%) in endometrioid and 2/8 (25%) in clear-cell adenocarcinomas and in H-ras gene 1/8 (13%) in mucinous and 2/29 (7%) in serous adenocarcinomas. Analysis of the results revealed no significant correlation between ras gene mutations and clinicopathological parameters or clinical outcome of this primary invasive ovarian carcinoma population. Our present data suggest that ras gene mutations in invasive ovarian carcinomas occur in 29% of Greek patients and are not associated with the differentiation of the epithelial cells or the response of patients to adjuvant platinum-based chemotherapy.     

Mutation of the PTEN tumor suppressor gene in endometrial hyperplasias

Mutation and deletion of the PTEN tumor suppressor gene occurs in about 40% of endometrial carcinomas. The purpose of this study was to determine whether PTEN mutations also are present in endometrial hyperplasias, which are premalignant precursors of invasive endometrial adenocarcinomas. Genomic DNA from 51 endometrial hyperplasias was extracted from paraffin blocks, and PCR was used to amplify the nine exons of the PTEN gene. These products were screened using single-strand conformation analysis, and variant bands were sequenced. Somatic mutations in the PTEN gene were seen in 10 of 51 cases (20%), and two mutations were found in one case. An identical 4-bp deletion in exon 8 was seen in three cases, and 8 of 11 PTEN mutations predicted truncated protein products. There was no higher frequency of PTEN mutations in endometrial hyperplasias with atypia (6 of 32; 19%) relative to those without atypia (4 of 19; 21%). These data suggest that inactivation of the PTEN tumor suppressor gene is an early event in the development of some endometrial cancers.     

MEN1 gene mutation analysis of sporadic adrenocortical lesions

To clarify the role of the MEN1 gene in the tumorigenesis of sporadic adrenocortical tumors, we performed a molecular study on 35 adrenocortical lesions including 6 hyperplasias, 19 adenomas and 10 carcinomas. Loss of heterozygosity (LOH) of the MEN1 gene was assessed by PCR using an intragenic (D11S4946) and 2 flanking microsatellite markers (D11S4936, PYGM) and/or fluorescence in situ hybridization (FISH) with a 40-kb cosmid probe containing the MEN1 gene. The complete coding sequence of the MEN1 gene was screened for mutations using non-radioactive, PCR-based single-strand conformation polymorphism (SSCP) analysis and MDE heteroduplex gel electrophoresis. PCR-LOH and FISH analyses performed in 29 tumors (PCR-LOH in 4, FISH in 17 and both in 8 tumors) revealed allelic deletion of the MEN1 locus in 8 (27.5%) and at 11q13 in 9 (31%) tumors. Furthermore, the frequency of LOH at 11q13 was significantly higher in adrenocortical carcinomas (60%) than in benign lesions (11%). Mutation analysis of tumor samples revealed 9 polymorphisms in 7 tumors (S145S, R171Q, R171Q together with L432L) but no mutations, with the exception of one adrenocortical adenoma. The latter tumor contained a somatic E109X stop codon mutation in exon 2 and a 5178-9G-->A splice mutation in intron 4, which was also detectable in various nontumorous tissues and blood indicative of a germ-line mutation. The patient, who had no clinical signs or family history of MEN1, later also developed a neuroendocrine carcinoma (atypical carcinoid) of the lung. Our findings indicate that inactivating mutations of the MEN1 tumor-suppressor gene appear not to play a prominent role in the development of sporadic hyperplastic or neoplastic lesions of the adrenal cortex and that the newly reported 5178-9G-->A splice mutation in intron 4 might cause a variant of the MEN1 phenotype.     

Type and number of Ki-ras point mutations relate to stage of human colorectal cancer

Point mutations in the Ki-ras gene belong to the genetic key events in tumorigenesis of colorectal cancer. The type and number of point mutations were detected in specimens from patients with colorectal carcinomas stages as Dukes B and C using single-stranded conformational polymorphism analysis and sequencing. G-A transitions in codon 12 were exclusively found in Dukes B tumors, G-T transversions mainly in Dukes C, and G-C transversions only in Dukes C tumors. Apparently, the G-T and G-C transversions are associated with metastatic behavior of colorectal carcinomas, while G-A transitions are not. In several samples, multiple point mutations could be detected in codon 12, the frequency of multiple mutations increasing with the stage of the tumor.     

K-RAS-2 gene mutations as predictors of metachronous colorectal adenomas

BACKGROUND: Mutations of K-RAS-2 gene and tumour suppressor genes have been found in both colorectal adenomas and carcinomas. The aim of this study was to investigate the prognostic value of K-RAS-2 gene mutations found in initial colorectal adenomas for predicting the risk of metachronous adenomas. METHODS: Genomic DNA was extracted from formalin-fixed and paraffin-embedded adenomas larger than 5 mm in diameter removed at the initial total colonoscopy between 1980 and 1982. All patients underwent colonoscopic follow-up for at least 10 years. The sequence of exon 1 of the K-RAS-2 oncogene was amplified with the polymerase chain reaction technique and screened for mutation by single-strand conformation polymorphism analysis. All suspected mutations were confirmed by direct DNA sequencing. The predictive value of K-RAS-2 gene mutations for the risk of metachronous adenomas was assessed by chi-square testing and logistic regression analysis. RESULTS: Of 54 patients 39 (72%) were male and 15 (28%) female. At the time the initial adenoma was removed, 31 (57%) patients were younger than 60, whereas 23 (43%) were 60 years or older. Point mutations of the K-RAS-2 oncogene were found in the index adenomas of 15 (27.7%) patients. Mutations were found more frequently in large (> or = 20 mm) adenomas and in adenomas with severe dysplasia (P = 0.0011 and P = 0.0310, respectively). There were no significant associations between K-RAS-2 mutations and anatomic location, histologic type, or number of synchronous initial lesions. Mutations were found predominantly at codon 12 with transversions from GGT to GTT (57%), from GGT to GAT (36%), and from GGT to TTT (one patient). The single mutation found at codon 13 showed a transversion from GGC to GAC. There were significant associations between size (> or = 20 mm) and K-RAS-2 mutation of the initial adenomas and the size (> 5 mm) of metachronous adenomas (P = 0.0259 and P = 0.0265, respectively). However, multivariate analysis showed that K-RAS-2 mutations did not provide a significant additional contribution to the prognostic value of the size of the initial adenoma (odds ratio, 7.62; 95% confidence interval (CI), 1.68-34.48) and the amount of villous structure (odds ratio, 0.22; 95% CI, 0.05-0.90) it contained. CONCLUSIONS: Patients with large (> or = 20 mm) adenomas and adenomas with K-RAS-2 mutations found at the initial examination have a significantly higher risk of developing large (> 5 mm) metachronous adenomas during surveillance. Multivariate analysis of initial adenoma characteristics showed that the risk of metachronous colorectal adenomas can be adequately estimated by the size and the histologic type of the largest initial adenoma and that K-RAS-2 mutations are of secondary importance only. Further studies based on a larger series will have to identify the adenoma characteristics that will help to improve follow-up strategies.     

p53 protein overexpression and K-ras codon 12 mutation in pancreatic ductal carcinoma: correlation with histologic factors

The correlation of p53 protein overexpression and the K-ras codon 12 mutation with histologic type, grade of cytologic atypia, depth of invasion and other histologic prognostic factors was studied in paraffin sections from 43 ductectatic- and 70 solid-type pancreatic ductal carcinomas. Overexpression of p53 was found in 23.3% (10/43) of ductectatic carcinomas (17.2% of intraductal and 35.7% of invasive carcinomas) and in 61.4% (43/70) of solid carcinomas. In ductectatic cancers, p53 overexpression was detected in 14.8% (4/27) of carcinomas with low-grade atypia (CAL), 50.0% (5/10) of carcinomas with high-grade atypia (CAH) and in 16.7% (1/6) of mixed low- and high-grade cancers. In the last group, expression was restricted to an area of CAH. In solid cancers, p53 overexpression did not differ by histologic type or grade. Overexpression of p53 and K-ras mutations did not correlate with histologic prognostic factors (lymphatic, venous and perineural invasion, and lymph node metastasis) in ductectatic and solid cancers or depth of invasion of solid carcinomas. Our data suggest that p53 alteration occurs at an early intraductal stage of solid carcinoma, irrespective of cellular atypia, but is low in ductectatic CAL and becomes higher in ductectatic CAH. K-ras mutation, present in a high percentage of tumors of all groups and not correlating with the factors above, showed no changes in frequency with tumor progression.     

The presence of K-12 ras mutations in duodenal adenocarcinomas and the absence of ras mutations in other small bowel adenocarcinomas and carcinoid tumors

BACKGROUND: Adenocarcinomas and carcinoid tumors are the most common malignant tumors of the small intestine. K-ras oncogene mutations at codon 12 are common in gastric, pancreatic, and colon carcinomas, with an incidence of 35-88%. K-ras mutations have not been extensively studied in either adenocarcinomas or carcinoid tumors of the small bowel. The purpose of this study was to determine whether ras mutations play an important role in the formation of these tumors. METHODS: Archival tissues from 28 adenocarcinomas and 22 carcinoid tumors of the small bowel were studied, along with archival tissues from 32 adenocarcinomas of the large bowel, which were used as controls. DNA from the small intestine tumors was analyzed for K-ras, H-ras, and N-ras oncogene mutations at codons 12, 13, and 61, using polymerase chain reaction and sequence specific oligonucleotide hybridization techniques. Large bowel adenocarcinomas were analyzed for K-ras mutations at codons 12 and 13. RESULTS: A point mutation of K-ras at codon 12 was detected in 4 of 28 (14.3%) of the small bowel adenocarcinomas, in 12 of 32 (37.5%) of the large bowel adenocarcinomas, and in 0 of 22 small intestine carcinoid tumors. No other K-ras, H-ras, or N-ras mutations were detected in any of the small bowel tumors. Each small intestine K-ras mutation was found in a duodenal adenocarcinoma (4 of 12 cases, 33%), whereas none occurred in 16 other jejunal or ileal adenocarcinomas. CONCLUSIONS: K-ras mutations appear to play a significant role in the pathogenesis of duodenal adenocarcinomas, but they do not appear to be important in the development of jejunal or ileal adenocarcinomas or of carcinoid tumors of the small intestine.     

Mutations and expression of the ras family genes in leukemias

The levels of expression and the incidence of codon 12 point mutations of the ras family genes were studied in 18 cases of leukemia, seven with acute myeloblastic leukemia (AML), three with acute lymphoblastic leukemia (ALL), four cases with chronic myelogenic leukemia (CML) and four cases with chronic lymphocytic leukemia (CLL). Elevated expression of the ras genes was found for 39%, 61% and 67% of the specimens for the H-ras, K-ras and N-ras, respectively. A trend was found between the overexpression of the N-ras gene and the acute leukemias: all 10 acute leukemias exhibited overexpression of the N-ras gene, while only two of the CML cases, both in blastic crisis, showed elevated levels of the N-ras gene. Codon 12 point mutations at the N-ras gene were found in two of seven cases (28%) with AML and one of four cases (25%) with CML. The only K-ras codon 12 point mutation was found in a patient with CLL. No mutations were found in the codon 12 of H-ras. Our data suggest that apart from the point mutations, overexpression of the ras family genes is important in the development of the disease.     

Glutamine-supplemented parenteral nutrition improves gut mucosa integrity and function in endotoxemic rats

Seventy-seven pancreatic adenocarcinomas (60 Spanish and 17 Italian) were tested for Ki-ras gene mutations by analysis of polymerase chain reaction amplified sequences. Mutations involving codon 12 (GGT; gly) were detected in 16 Italian and 46 Spanish cases (80.5% in total). All Italian mutations involved the second base and were G to A transitions (GAT; asp) in 8 cases and G to T transversions (GTT; val) in the remaining 8. Forty-two Spanish mutations were characterized. Thirty-eight were at the second and 4 at the first base: asp in 24 cancers, val in 14, arg (CGT) in 2 and cys (TGT) in 2. Previous European studies and our present data show that 149 of the 186 pancreatic cancers harbored a codon 12 Ki-ras mutation (80%), the large majority affecting the second base (73%), with a transitions/transversions ratio of 1.3:1. However, the mutational pattern of cancers of the different European countries shows remarkable differences, both in the site of the mutation (first or second base) and in the ratio of transitions over transversions. Moreover, a significant subgroup of pancreatic carcinomas do not harbor Ki-ras mutations. The classification of pancreatic cancers, according to the presence or absence, and type of Ki-ras mutation, may be of importance in epidemiological studies. A critical reappraisal of existing epidemiological data, through a retrospective genotypic study using paraffin-embedded cancer samples, may reveal significant correlations with specific genotoxic agents.     

Prognostic impact of mutated K-ras gene in surgically resected non-small cell lung cancer patients

Mutated K-ras oncogenes have been detected in a third of lung adenocarcinomas, located usually in codon 12, its presence correlating negatively with survival. To further define the role of K-ras point mutations in non-small cell lung cancer, we studied the presence of mutated K-ras genes in surgical specimens from 66 patients. Polymerase chain reaction was performed from sections of formalin-fixed paraffin-embedded tissue. We screened for point mutations in codons 12, 13 and 61 of the K-ras gene by dot blot hybridization analysis with mutation-specific oligonucleotide probes. Ras gene mutations were present in 13 of 66 carcinomas (20%), nine in codon 12 and four in codon 61. Three squamous cell carcinomas harbored two different point mutations in K-ras codon 12. Mutated K-ras genes were found more frequently in squamous cell carcinomas (eight of 38) than in adenocarcinoma (three of 22). Analysis of nucleotide sequence disclosed a multifarious mutation pattern of K-ras codon 12, where the most common conversion was from glycine (GGT) to valine (GTT). K-ras point mutation positive subset had poorer survival, nine of the 13 patients died during the follow-up period as compared with 22 of 53 patients with no mutation in the K-ras gene (P = 0.01). The difference was also strikingly significant when stratified according to node status.     

Angiogenesis correlates with vascular endothelial growth factor expression but not with Ki-ras oncogene activation in non-small cell lung carcinoma

A total of 195 non-small cell lung carcinoma (NSCLC) specimens were studied for the presence of mutations in their ras family genes, for tumor vascularity, and for their immunostaining pattern with an antibody to vascular endothelial growth factor (VEGF). ras mutation was found in 37 of 104 (34.6%) adenocarcinoma specimens, in 0 of 64 squamous cell carcinomas, and in 2 of 27 (7.4%) large cell undifferentiated carcinomas. All mutations were found on the Ki-ras gene, with 37 (95%) of them on codon 12 and the remaining 2 on codon 13. Thirty (77%) of the mutations were G to T transversions. There was a correlation between increasing tumor vascularity and VEGF immunostaining score, but there was no correlation between either of them with the activation of the ras oncogene. A study of VEGF mRNA expression in 14 NSCLC cell lines also demonstrated a lack of correlation between the constitutive expression levels of VEGF and the presence or absence of ras mutation in these cell lines. The results suggest that VEGF is a major angiogenesis factor in NSCLC but that other factors beside ras mutations may influence tumor vascularity in these tumors. The two parameters may potentially serve as independent prognostic factors in NSCLC.     

Expression of Hras-p21 and keratin K13 in UVR-induced skin tumors in Sencar mice

An ultraviolet radiation (UVR)-induced Sencar mouse skin carcinogenesis model was established to investigate the expression of Hras-p21 and keratin K13 in different stages of carcinogenesis, including UV-exposed nontumor skin, papillomas, squamous-cell carcinomas (SCCs), and malignant spindle-cell tumors (SCTs). Expression of Hras-p21 and K13 was examined in paraffin-embedded tumor sections by using immunohistochemical, immunofluorescent, and double staining techniques with specific antibodies. Positive Hras-p21 staining was detected in 1/3 (33%) papillomas, 24/36 (67%) of SCCs, but not in UVR-exposed nontumor skin or SCTs. Positive staining of the malignant progression marker K13 was found in 22/36 (61%) of SCCs only. Coexpression of Hras-p21 and K13 was found in 17/36(47%) SCCs. H-ras exons 1 and 2 were amplified from skin/tumor sections by using nested polymerase chain reaction (PCR). PCR-based single-strand conformation polymorphism (SSCP) analysis and gene sequencing revealed three point mutations, one in UVR-exposed nontumor skin (codon 56), and two in SCCs (codons 13 and 21). There were no clear relationships between point mutations of H-ras and the positive staining of Hras-p21 and K13. These results indicate that overexpression of ras-p21 in conjunction with aberrant expression of K13 is a frequent event in UVR-induced SCCs in Sencar mouse skin. Point mutation of the H-ras gene appeared to be a rare event in UVR skin carcinogenesis and not to be responsible for overexpression of Hras-p21.     

Aromatase activities of endometrial carcinomas and both basic and clinical analyses of endometrial hyperplasia as a premalignant disease

Paraffin-embedded materials obtained from 117 cases of endometrial hyperplasia and 84 cases of carcinoma were used for measurement of both ki-ras and p53 gene mutation and aromatase (ARO) and TGF-alpha immunostaining. The overall incidence of ki-ras mutations in the hyperplasia specimens (16%) was similar to the incidence detected in carcinomas (18%). None of 117 endometrial hyperplasias were found to have mutations in the p53 gene, whereas mutations were seen in 3 (13.3%) endometrial carcinomas. The intensity of both ARO and TGF-alpha immunostaining was increased in glands of both hyperplasia and carcinoma, and also in the interstitium of carcinoma. The positive sites of both ARO and TGF-alpha were almost the same, with an incidence below 40% in both hyperplasias and carcinomas. The cultured cells of endometrial carcinoma showed aromatase activity below MCF-7 cells, because testosterone was converted to estradiol (E2). TGF-alpha induced cell growth with at an optimal concentration. In HEC-59 cells, TGF-alpha increased both ARO-activity and mRNA. Some promoters on ARO-exon 1 in HEC-59 cells were different from those in BeWo cells. Progesterone inhibited the E2-induced excretion of pre TGF-alpha in endometrial carcinoma cells. These findings suggest that endometrial hyperplasia can be a premalignant condition of carcinoma, and can be initiated by both ki-ras codon 12 mutation and abnormal activity of ARO induced by TGF-alpha. In addition, HEC-59 cells may possess autocrine/paracrine properties involving ARO, E2 and TGF-alpha.     

Combined effects of insulin treatment and adipose tissue-specific agouti expression on the development of obesity

BACKGROUND & AIMS: Infantile and childhood liver tumors have been found in 0.42% of individuals with a germline mutation in the adenomatous polyposis coli (APC) gene. This study analyzed a hepatocellular adenoma of a 2-year-old child at risk for familial adenomatous polyposis to identify genetic alterations in hepatic tumors initiated by APC germline mutations. METHODS: Mutation screening was performed for the APC gene (protein truncation test and DNA sequence analysis), p53 gene (complementary DNA cloning and sequencing), and members of the Ras gene family (complementary DNA sequence analysis). RESULTS: Both the mother and child had a germinal CGA-->TGA transition at codon 1451 leading to an Arg1451Ter stop mutation in the APC gene. Loss of the wild-type APC allele as a second hit revealed hemizygosity of the inherited mutation in the tumor. Furthermore, a CGC-->CAC transition in the p53 gene of the adenoma resulted in an Arg-->His missense mutation in codon 175. No loss of heterozygosity was detected at the p53 locus. Ras gene mutations were not found. CONCLUSIONS: Biallelic inactivation of APC gene and p53 mutation are early events in hepatocellular tumorigenesis. Additional reports will confirm whether inherited APC gene mutations between codon 1444 and 1578 increase the risk for hepatic tumors.