No involvement of Ki-ras or p53 gene mutations in colitis-associated rat colon tumors induced by 1-hydroxyanthraquinone and methylazoxymethanol acetate

Murine Model for Colitis-Associated Cancer of the Colon

Inflammatory bowel disease (IBD), including ulcerative colitis (UC) and Crohn's disease (CD), significantly increases the risk for development of colorectal cancer. Specifically, dysplasia and cancer associated with IBD (colitis-associated cancer or CAC) develop as a result of repeated cycles of injury and healing in the intestinal epithelium. Animal models are utilized to examine the mechanisms of CAC, the role of epithelial and immune cells in this process, as well as the development of novel therapeutic targets. These models typically begin with the administration of a carcinogenic compound, and inflammation is caused by repeated cycles of colitis-inducing agents. This review describes a common CAC model that utilizes the pro-carcinogenic compound azoxymethane (AOM) followed by dextran sulfate sodium (DSS) which induces the inflammatory insult.

Inhibition of autophagy exerts anti-colon cancer effects via apoptosis induced by p53 activation and ER stress

BACKGROUND

Although some molecularly targeted drugs for colorectal cancer are used clinically and contribute to a better prognosis, the current median survival of advanced colorectal cancer patients is not sufficient. Autophagy, a basic cell survival mechanism mediated by recycling of cellular amino acids, plays an important role in cancer. Recently, autophagy has been highlighted as a promising new molecular target. The unfolded protein response (UPR) reportedly act in complementary fashion with autophagy in intestinal homeostasis. However, the roles of UPR in colon cancer under autophagic inhibition remain to be elucidated. We aim to clarify the inhibitory effect of autophagy on colon cancer.

METHODS

We crossed K19 (CreERT) and Atg5 (flox/flox) mice to generate Atg5 (flox/flox)/K19 (CreERT) mice. Atg5 (flox/flox)/K19 (CreERT) mice were first treated with azoxymethane/dextran sodium sulfate and then injected with tamoxifen to inhibit autophagy in CK19-positive epithelial cells. To examine the anti-cancer mechanisms of autophagic inhibition, we used colon cancer cell lines harboring different p53 gene statuses, as well as small interfering RNAs (siRNAs) targeting Atg5 and immunoglobulin heavy-chain binding protein (BiP), a chaperone to aid folding of unfolded proteins.

RESULTS

Colon tumors in Atg5 (flox/flox)/K19 (CreERT) mice showed loss of autophagic activity and decreased tumor size (the total tumor diameter was 28.1 mm in the control and 20.7 mm in Atg5 (flox/flox)/K19 (CreERT) mice, p = 0.036). We found that p53 and UPR/endoplasmic reticulum (ER) stress-related proteins, such as cleaved caspase 3, and CAAT/enhancer-binding protein homologous protein, are up-regulated in colon tumors of Atg5 (flox/flox)/K19 (CreERT) mice. Although Atg5 and BiP silencing, respectively, increased apoptosis in p53 wild type cells, Atg5 silencing alone did not show the same effect on apoptosis in p53 mutant cells. However, co-transfection of Atg5 and BiP siRNAs led to increased apoptosis in p53 mutant cells.

CONCLUSIONS

Blocking autophagy has potential in the treatment of colon cancer by inducing apoptosis via p53 and ER stress, and suppressing the UPR pathway is a valid strategy to overcome resistance to autophagic inhibition.

The AOM/DSS murine model for the study of colon carcinogenesis: From pathways to diagnosis and therapy studies

Colorectal cancer (CRC) is a major health problem in industrialized countries. Although inflammation-linked carcinogenesis is a well accepted concept and is often observed within the gastrointestinal tract, the underlying mechanisms remain to be elucidated. Inflammation can indeed provide initiating and promoting stimuli and mediators, generating a tumour-prone microenvironment. Many murine models of sporadic and inflammation-related colon carcinogenesis have been developed in the last decade, including chemically induced CRC models, genetically engineered mouse models, and xenoplants. Among the chemically induced CRC models, the combination of a single hit of azoxymethane (AOM) with 1 week exposure to the inflammatory agent dextran sodium sulphate (DSS) in rodents has proven to dramatically shorten the latency time for induction of CRC and to rapidly recapitulate the aberrant crypt foci–adenoma–carcinoma sequence that occurs in human CRC. Because of its high reproducibility and potency, as well as the simple and affordable mode of application, the AOM/DSS has become an outstanding model for studying colon carcinogenesis and a powerful platform for chemopreventive intervention studies. In this article we highlight the histopathological and molecular features and describe the principal genetic and epigenetic alterations and inflammatory pathways involved in carcinogenesis in AOM/DSS–treated mice; we also present a general overview of recent experimental applications and preclinical testing of novel therapeutics in the AOM/DSS model.

The effects of oxidative DNA damage and mutations in the p53 protein on cells of the colonic mucosa with and without the fecal stream: an experimental study in rats

OBJECTIVE

The aim of this study was to investigate the levels of oxidative DNA damage and p53 mutations in an experimental model of diversion colitis.

MATERIAL AND METHODS

Sixty rats were divided into three groups with 20 animals in accordance with the sacrifice was carried out 6, 12 and 18 weeks. For each group, 15 animals were subjected to diversion of the fecal stream through colostomy in the left proximal colon and distal mucous fistula (experimental group), and five to a laparotomy without deviation of the fecal stream (control group). The presence of colitis was evaluated by inflammatory grading scale. Mutations in the p53 protein were evaluated by immunohistochemistry with primary antibody with cross-reactivity for rats. The oxidative DNA damage was measured using the comet assay. To statistical analysis were used the Student's t, Mann-Whitney and Kruskal-Wallis test adopting a significance level of 5% (p < 0.05).

RESULTS

Colon segments without fecal stream showed greater degree of inflammation when compared to animals with preserved fecal stream (p = 0.01). The levels of oxidative stress were significantly higher in segments without fecal stream (p < 0.0001) and increased with the time of fecal diversion (p = 0.007). The levels of oxidative DNA damage are directly related to tissue degree of inflammation. There were no mutations in the p53 protein in the segments without fecal stream regardless of time of exclusion considered.

CONCLUSION

Despite higher levels of oxidative damage to nuclear DNA on segments without fecal stream that developed colitis mutations in the p53 protein were not detected.

A novel inflammation-related mouse colon carcinogenesis model induced by azoxymethane and dextran sodium sulfate

To develop an efficient animal model for colitis-related carcinogenesis, male Crj: CD-1 (ICR) mice were given a single intraperitoneal administration (10 mg/kg body weight) of a genotoxic colonic carcinogen, azoxymethane (AOM), and a 1-week oral exposure (2% in drinking water) to a non-genotoxic carcinogen, dextran sodium sulfate (DSS), under various protocols. At week 20, colonic neoplasms (adenocarcinomas, 100% incidence with 5.60 +/- 2.42 multiplicity; and adenomas, 38% incidence with 0.20 +/- 0.40 multiplicity) with dysplastic lesions developed in mice treated with AOM followed by DSS. Protocols in which AOM was given during or after DSS administration induced a few tubular adenomas or no tumors in the colon. Immunohistochemical investigation of such dysplasias and neoplasms revealed that all lesions were positive for beta-catenin, cyclooxygenase-2 and inducible nitric oxide synthase, but did not show p53 immunoreactivity. The results indicate that 1-week administration of 2% DSS after initiation with a low dose of AOM exerts a powerful tumor-promoting activity in colon carcinogenesis in male ICR mice, and may provide a novel mouse model for investigating colitis-related colon carcinogenesis and for identifying xenobiotics with modifying effects.

No involvement of beta-catenin gene mutation in gastric carcinomas induced by N-methyl-N-nitrosourea in male F344 rats

The agent N-methyl-N-nitrosourea (MNU) is a direct acting carcinogen and induces well-differentiated adenocarcinoma on the rat gastric mucosa. In this study, 27 histopathologically verified gastric carcinomas induced in male F344 rats were analyzed for mutations in the N-terminal phosphorylation sites (codons 1-51) of the beta-catenin gene by using polymerase chain reaction (PCR)-single strand conformation polymorphism (SSCP) assays. In parallel studies, the specific localization of the beta-catenin protein was also examined by immunohistochemical analysis. No mutations in the beta-catenin gene were found in any of 27 gastric carcinomas induced by MNU. Immunohistochemical analysis resulted in the beta-catenin protein to be localized in the plasma membrane but cytoplasmic and/or nuclear accumulation of beta-catenin was not identified in any of these carcinomas. These results suggest that mutations in the beta-catenin gene are less contributory to the development of rat gastric carcinomas induced by MNU. This animal model may provide a system for evaluating the mechanism of human gastric carcinogenesis that is not associated with beta-catenin gene mutations.

Enhanced colon carcinogenesis induced by azoxymethane in min mice occurs via a mechanism independent of beta-catenin mutation

The multiple intestinal neoplasia (min) mouse is a well-established cancer model in which loss of a single copy of the APC protein predisposes mice to the development of numerous tumors in the intestine. We have developed a novel variation of the min mouse model by using azoxymethane (AOM) to cause an increase in tumor incidence, number and size. Thus, treatment of min mice with AOM resulted in 2.6-, 6.3- and 5.9-fold increases in overall tumor incidence, multiplicity and size, respectively, when compared to wild type C57BL/6J mice treated with AOM. Furthermore, adenocarcinomas of the colon, which are otherwise relatively rare in min mice, increased in incidence (P<0.004), multiplicity (P<0.005), and size (P<0.02) in the AOM-treated min mice when compared to control untreated min mice. Of these adenocarcinomas, the number of poorly plus moderately differentiated adenocarcinomas was also significantly higher in the AOM-treated min mice (P<0.008). Thirty-seven histopathologically verified colon tumors (eight adenomas, five carcinoma in situ and 24 adenocarcinomas) induced in min mice and in C57BL/6J mice after treatment with or without AOM were analyzed for mutations in the beta-catenin gene or de novo mutations in the Apc gene. No mutations in the beta-catenin gene were found in any of colon tumors in min mice with or without treatment with AOM. However, mutations in either the beta-catenin gene or the Apc gene were found in tumors induced in C57BL/6J mice by AOM. These results suggest that mutations in the beta-catenin gene are less contributory to tumor development in min mice, as is the case in familial adenomatous polyposis (FAP) in humans. However, de novo mutations in either the Apc or beta-catenin gene can play a role in tumor development in C57BL/6J mice treated with AOM. The differences in mutation status between min and C57BL/6J mice may indicate different genetic pathways for developing colon tumors. These two experimental systems may, therefore, be useful animal models of human colon carcinomas in patients with FAP and in patients with sporadic colon carcinomas.

Different mutation status of the beta-catenin gene in carcinogen-induced colon, brain, and oral tumors in rats

Mutations in the region corresponding to the N-terminal phosphorylation sites (codons 1-51) of the rat beta-catenin gene (Ctnnb1) were investigated in rat colon tumors induced by 1-hydroxyanthraquinone (1-HA) plus methylazoxymethanol (MAM) acetate, by using polymerase chain reaction (PCR)-single-strand conformation polymorphism (SSCP) analysis. The beta-catenin gene was also screened for mutations in rat brain and oral tumors induced by ethyl nitrosourea (ENU) and 4-nitroquinoline 1-oxide (4-NQO), respectively. In colon tumors, beta-catenin gene mutations were found in two of three adenomas (67%) and 26 of 28 adenocarcinomas (93%), with a total incidence of 90% (28 of 31 adenomas plus adenocarcinomas). Eight (29%) were (34)G-->T (second position), eight (29%) were (32)G-->A (first position), five (18%) were (34)G-->A (first position), five (18%) were (41)C-->T (second position), one (4%) was (34)G-->A (second position), and one (4%) was (32)A-->G (second position), mutations, resulting in the substitutions of Gly(34)-->Val, Asp(32)-->Asn, Gly(34)-->Arg, Thr(41)-->Ile, Gly(34)-->Glu, and Asp(32)-->Gly, respectively. The (34)G-->T (second position) mutations found in this study were unique compared to those found in other carcinogen-induced rat colon carcinogenesis models. In contrast, beta-catenin gene mutations were not found in either the brain or oral tumors. These results suggest that mutations in the beta-catenin gene in rat tumors occur in specific tissues or organ sites and in a carcinogen-specific manner. Thus, the mutation spectrum in the beta-catenin gene is organ- and chemical carcinogen-specific.

Non-involvement of the K-ras mutation in colon carcinogenesis promoted by dietary deoxycholate in azoxymethane-treated rats

Fisher-344 rats, whose ileum or jejunum had been surgically removed to change the influx of bile acids into the colon, were intraperitoneally administered with azoxymethane and fed on a diet containing deoxycholate for 39 weeks to induce colon cancer. Fecal bile acids in the ileum-resected group were 1.5-times and serum bile acids were about half of those in the jejunum-resected group. As a result, the incidence and number of tumors were higher in the ileum-resected group. In the total of 59 colon tumors (40 were in the ileum-resected group and 19 in the jejunum-resected group), 56 were carcinomas, including two well-differentiated invasive and two mucinous carcinomas found in the ileum-resected rats. However, only three carcinomas, two invasive and one non-invasive, had the K-ras mutation. These results demonstrate that the K-ras mutation was not essentially involved in deoxycholate-promoted colon carcinogenesis.

Dysplasia and cancer in the dextran sulfate sodium mouse colitis model. Relevance to colitis-associated neoplasia in the human: a study of histopathology, B-catenin and p53 expression and the role of inflammation

Animal models of colitis, which develop dysplasia and cancer similar to human ulcerative colitis are needed to further investigate the dysplasia cancer sequence. This study describes the expression of B-catenin and p53 along with the histopathology and inflammation scores as they relate to dysplasia and cancer in the dextran sulfate sodium (DSS) colitis model. Swiss Webster mice were fed with 5% DSS as follows: group A, four cycles of DSS, 84 days total (1 cycle = 7 days DSS + 14 days H(2)O); group B, four cycles DSS followed by 120 days H(2)O, 204 days total; group C, 7 days DSS followed by 180 days H(2)O, 187 days total; group D, 7 days DSS followed by 90 days H(2)O, 97 days total. The incidences of dysplasia and/or cancer were 15.8, 37.5, 18.1 and 0% in groups A-D, respectively. Dysplasia and/or cancer occurred as flat lesions or as dysplasia-associated lesion or mass (DALM) as observed in the human. Thirty-three percent of cancers had associated dysplasia. Within group A, inflammation scores were significantly higher in animals with dysplasia and/or cancer compared with those without dysplasia and/or cancer (P < 0. 05-P < 0.0001). Inflammation scores were significantly higher in animals with cancers versus those with dysplasia (P < 0.015) and in flat dysplasia and/or cancer versus DALM (P < 0.0042). B-catenin showed translocation from the cell membrane to the cytoplasm and/or nucleus in 100% of DALM and 5.8% of flat dysplasia and/or cancer. A total of 94.2% of flat dysplasia and/or cancer had exclusive cell membrane expression compared with 0% DALM (P < 0.0001). Only 7.4% of dysplasia and/or cancer showed nuclear expression of p53. In colitis-associated dysplasia and/or cancer in the DSS model: (i) histology resembles that in the human; (ii) inflammation plays a significant role in the dysplasia cancer sequence and whether dysplasia and/or cancer grows as a flat lesion or a DALM; (iii) the early molecular pathways are different for flat dysplasia and/or cancer versus DALM, with nuclear/cytoplasmic translocation of B-catenin as an early event in DALM but not flat dysplasia and/or cancer; and (iv) p53 has little or no role in dysplasia and/or cancer. This well characterized model provides an excellent vehicle for studying the roles of inflammation, the molecular events and the role of chemopreventive agents in colitis-associated neoplasia.

The effect of dietary folate on Apc and p53 mutations in the dimethylhydrazine rat model of colorectal cancer

Dietary inadequacy of folate enhances and folate supplementation suppresses colorectal carcinogenesis in the dimethylhydrazine rat model. Folate is an essential factor for DNA methylation and the de novo biosynthesis of nucleotides, aberrations of which play important roles in mutagenesis. This study investigated whether the mutational hot spots of the Apc and p53 genes for human colorectal cancer are mutated in dimethylhydrazine-induced colorectal neoplasms and whether dietary folate can modulate mutations in these regions. Rats were fed diets containing 0, 2 (basal requirement), 8 or 40 mg folate/kg diet. Five weeks after diet initiation, dimethylhydrazine was injected weekly for 15 weeks. Mutations were determined by direct sequencing in 11 low and seven high grade dysplasias and 13 invasive adenocarcinomas. A total of six Apc mutations were found in four dysplastic and carcinomatous lesions: two in two low grade dysplasias, two in one high grade dysplasia and two in one adenocarcinoma. All mutations were single base substitutions, four of which were A:T-->G:C transitions. Five of the six mutations were located upstream from the region corresponding to the human APC mutation cluster region. Dietary folate had no effect on the frequency and type of Apc mutations. No mutations were detected in exons 5-9 of the p53 gene in neoplastic lesions. These data suggest that in the dimethylhydrazine rat model of colorectal cancer, the Apc gene is mutated in early stages, albeit to a lesser degree than observed in human colorectal cancer, whereas the mutational hot spot of the p53 gene for human colorectal cancer is not commonly mutated. Although the low frequency of Apc mutations and the small number of neoplasms studied in this study might have precluded our ability to observe modulatory effects of folate, dietary folate appears to have no significant effect on Apc and p53 mutations.

p53 mutation decreased radiosensitivity in rat yolk sac tumor cell lines

PURPOSE

We reported that two established rat yolk sac tumor cell lines differ in their radiosensitivity by 1.7 fold, and the variation is most likely manifested by the differences seen in their apoptotic response. We investigated the relationship between radiosensitivity and p53 in these cell lines.

METHODS AND MATERIALS

We assessed the status of p53 in cell lines by polymerase chain reaction-single strand conformation polymorphism (PCR-SSCP) and sequence analysis, and also analyzed protein expression of p53, p21, and bax as a function of time after irradiation to determine the signal transduction for p53 by immunoblotting.

RESULTS

A band shift was observed only in exon 7 for the radioresistant NMT-1R cells and no band shift was detected for the radiosensitive NMT-1 cells. A band shift was confirmed also at the mRNA level. Exon 7 of p53 DNA showed a three base substitution of DNA at codon 267 to 268. Expression of p53, p21, and bax proteins in NMT-1R cells did not change after 10 Gy irradiation; however, in NMT-1 cells, the expression of these proteins was increased from 1-12 h after irradiation.

CONCLUSION

A loss of p53 function by radiation-induced mutation of p53 decreased the radiosensitivity in these cell lines.

Microsatellite instability is infrequent in azoxymethane-induced rat intestinal tumors: An assessment by capillary electrophoresis

A rat model of colon cancer in which tumors are induced by azoxymethane (AOM) is frequently used to study putative environmental agents that may modify the risk of human colon cancer development. In order to evaluate the usefulness of this model for human risk assessment, a comparison of the molecular changes associated with tumorigenesis in the rat model with those in human colon cancer is desirable. Microsatellite instability (MSI), an alteration in length of short repetitive DNA sequences associated with defective DNA mismatch repair, is an important molecular characteristic of many human colon tumors. Intestinal tumors were induced in male Fischer 344 rats injected with 15 mg/kg body wt AOM in four weekly doses. Thirteen intestinal tumors were examined for MSI at 10 different microsatellite loci, using a capillary electrophoresis (CE) method for accurate assessment of DNA length. This method was shown to have a resolution of 1 bp for a 140-bp PCR product and to be capable of detecting one mutant sequence within a background of 10 wild-type sequences. The CE method also readily distinguished a known MSI-positive human tumor sample from its matching control sample. Among the 13 rat intestinal tumors examined, only one had MSI, which was present at only a single locus. We conclude that, unlike sporadic human colon tumors in which 15-30% of tumors have MSI (usually at multiple loci), MSI is very rare in AOM-induced rat intestinal tumors.

Frequent mutations of the rat beta-catenin gene in colon cancers induced by methylazoxymethanol acetate plus 1-hydroxyanthraquinone

Recent evidence suggests that the beta-catenin gene (CTNNB1) acts as an oncogene, and some human colon tumors with an intact APC gene have activating mutations in CTNNB1. In this study, mutations in the region corresponding to N-terminal phosphorylation sites (codons 1-51) of the rat Ctnnb1 gene were investigated in 20 colon tumors associated with ulcerative colitis and induced with methylazoxymethanol acetate and 1-hydroxyanthraquinone. Ninety percent (18 of 20) of the tumors induced in male F344 rats harbored mutations, which were detected in three of four adenomas (75%) and 15 of 16 adenocarcinomas (94%). Of 18 total missense mutations, 13 (72%) were G-->A transitions at position 101, three were G-->A transitions at position 94, and two were C-->T transitions at position 122, resulting in the amino acid substitutions Gly34-->Glu, Asp32-->Asn, and Thr41-->Ile, respectively. Although there were no mutations in the Apc gene, as we previously reported in the same tumor samples, the results obtained in this study strongly implicate the Apc-beta-catenin-T-cell factor (Tcf) signaling pathway in methylazoxymethanol acetate, 1-hydroxyanthraquinone-induced colon carcinogenesis.

Absence of PhIP adducts, p53 and Apc mutations, in rats fed a cooked beef diet containing a high level of heterocyclic amines

Meat cooked at high temperatures contains mutagens and carcinogens known as heterocyclic amines (HCA). Cooking temperature and time determine the amount of HCA produced. The present study examined the DNA of liver, colon, and stomach from rats fed a high level of HCA for 27 weeks. Male Sprague-Dawley rats were fed a high-fat AIN-76A-based diet containing 60% by weight cooked beef containing a high level of HCA, especially 2-amino-1-methyl-6-phenylimidazo[4,5-b]pyridine (PhIP, 72 ng/g cooked beef), the most abundant HCA in cooked meat products. At the end of 27 weeks the rats were terminated, and small portions of liver, colon, and stomach were quick-frozen in liquid nitrogen. The DNA was isolated from the thawed tissue by phenol-chloroform extraction, and the genomic DNA was analyzed for the presence of PhIP adducts by 32P-postla-beling analysis. The DNA was also used in polymerase chain reactions to amplify the rat p53 and Apc genes, then direct dye-terminator DNA sequencing was carried out. Results showed no PhIP adducts in any tissue. In addition, no signature p53 or Apc gene mutations were seen in colon or stomach DNA. These results indicate that the high level of HCA present in a diet of well-cooked meat does not cause 1) persistent PhIP adducts similar to those produced by feeding pure PhIP at high doses or 2) p53 and Apc gene mutations in nontumor tissue.

Assessment of mutations in Ki-ras and p53 in colon cancers from azoxymethane- and dimethylhydrazine-treated rats

Mutations in the Ki-ras oncogene and the p53 tumor suppressor gene are known to occur at high frequencies in human colon cancers. We measured the frequency of mutations in these two genes in colon adenocarcinomas obtained from a widely used experimental model of human colon carcinogenesis: F344 rats treated with the carcinogens azoxymethane (AOM) or dimethylhydrazine (DMH). We detected codon 12 mutations in Ki-ras in approximately 60% of colon adenocarcinomas induced by either carcinogen. We characterized the rat p53 intron-exon junctions to construct primers for polymerase chain reaction amplification of this gene. We discovered that the rat p53 gene was structurally different from the human p53 gene, as the rat gene was missing one intron between exons 6 and 7. Both single-stranded DNA conformational polymorphism analysis and direct DNA sequencing of the highly conserved regions of rat exons 5-7 were conducted because the corresponding human regions (exons 5-8) have been reported as being mutated most frequently in human colon cancers. Using these methods, we were unable to identify any p53 mutations in the highly conserved regions of exons 5-7 in either AOM- or DMH-induced colon adenocarcinomas. These data confirm that Ki-ras was mutated in most colon cancers in AOM- or DMH-treated rats but indicate that molecular alterations in the p53 gene, if they occur in this animal model, are different from most p53 mutations in human colon cancers.

WAF1 expression and p53 mutations in human colorectal cancers

The expression of the WAF1 gene was examined in the tissues of primary colorectal cancers and of adjacent non-neoplastic mucosas by Western blot analysis. p53 mutations of these cancer tissues were also analyzed by the polymerase chain reaction/single-strand conformation polymorphism followed by direct sequencing. Missense mutations of p53 were recognized in 19 out of 40 cases. Five cancers (12.5%) displayed much lower expression of WAF1 than did their corresponding mucosas, and all of them contained mutant p53. Fourteen cancers (35%) expressed the same level of WAF1 as their mucosas, and 5 of them had mutant p53. Twenty-one cancers (52.5%) had much higher WAF1 expression than their mucosas, and 9 of them had mutant p53. When Duke's classification was applied to these colorectal cancers, it was found that the cancers with reduced expression of WAF1 basically coincided with late (C or D) stages (4 out of 5 cases), while the cancers with higher WAF1 expression were consistent with early (A or B) stages (17 out of 21 cases). Down-regulation of WAF1 in colorectal cancer tissues may be implicated in tumor progression.

Infrequent Ha-ras mutations and absence of Ki-ras, N-ras, and p53 mutations in 4-nitroquinoline 1-oxide-induced rat oral lesions

The alkylating agent 4-nitroquinoline 1-oxide (4-NQO) is a powerful carcinogen and induces squamous cell hyperplasia, squamous cell dysplasia, papilloma, and squamous cell carcinoma (SCC) in rat oral epithelia. Oral cancers induced by a single application of 4-NQO develop through a multistage process in a way similar to the development of this cancer in humans. In this study, mutations in exons 1 and 2 of Ki-ras, N-ras, and Ha-ras and exons 4-7 of p53 were examined by polymerase chain reaction (PCR)-single strand conformation polymorphism (SSCP) analysis, followed by PCR-direct sequencing for the confirmation of mutations. Samples for the mutation analysis were obtained from dysplasias, papillomas, and SCCs on the tongue epithelia induced in F344 rats by adding 4-NQO (20 ppm) to their drinking water for 8 wk. The Ha-ras mutations (61A-->T transversions in the second position) were found in five of 29 (17%) samples (one dysplasia and four SCCs). However, no mutations were detected in either Ki-ras, N-ras, or p53 under two different conditions of PCR-SSCP analysis. We suggest that some neoplasms in oral carcinogenesis induced by 4-NQO may involve Ha-ras mutations but not mutations in Ki-ras, N-ras, or p53. The 4-NQO-induced rat oral carcinogenesis model may provide a system for evaluation of the mechanisms of multistage oral carcinogenesis associated with Ha-ras mutation without Ki-ras, N-ras, or p53 mutation.