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Query: UMLS:C0596263 (
carcinogenesis
)
64,820
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
The frequency and mutation spectra of proto-oncogene activation in hepatocellular neoplasms induced by tetrachloroethylene, trichloroethylene and dichloroacetic acid were examined to help define the molecular basis for their carcinogenicity. H-ras codon 61 activation was not significantly different among dichloroacetic acid- and trichloroethylene-induced and combined historical and concurrent control hepatocellular tumors (62%, 51% and 69% respectively). The mutation spectra of H-ras codon 61 mutations showed a significant decrease in AAA and increase in CTA mutations for dichloroacetic acid- and trichloroethylene-induced tumors when compared to combined controls. The H-ras codon 61 mutation frequency for tetrachloroethylene-induced tumors was significantly lower (24%) than that of combined controls and also that of the two other chemicals. Mutations at codons 13 and 117 plus a second exon insert contributed 4% to the total H-ras frequencies for trichloroethylene and tetrachloroethylene. There was also a higher incidence of
K-ras
activation (13%) in tetrachloroethylene-induced tumors than in the other chemically induced or control tumors. Four liver tumors were found to contain insertions of additional bases within the second exon of K- or H-ras. These findings suggest that exposure to dichloroacetic acid, trichloroethylene and tetrachloroethylene provides a selective growth advantage to spontaneously occurring mutations in codon 61 of H-ras and, at the same time, is responsible for a small number of unique molecular lesions suggestive of either a random genotoxic mode of action or a non-specific result of secondary DNA damage. However, the absence of ras activation in many of the liver neoplasms suggests that alternative mechanisms are also important in B6C3F1 mouse hepatocarcinogenesis.
Carcinogenesis
1994 Oct
PMID:ras proto-oncogene activation in dichloroacetic acid-, trichloroethylene- and tetrachloroethylene-induced liver tumors in B6C3F1 mice. 795 63
N-methyl-N-nitrosourea (MNU) induces thymic lymphomas in AKR mice after a 2-3 month latency. This study shows that hormonal factors profoundly influence MNU-induced lymphomagenesis. Tumor development is accelerated in females compared to males, regardless of whether a single high dose or multiple low doses of MNU are administered. Testosterone is implicated in this phenomenon, since castrated mice develop MNU-induced lymphomas with the same latency as intact females, while ovariectomized females have the same pattern of tumor development as intact females. Furthermore, reconstitution experiments demonstrated that testosterone replacement suppresses MNU-induced lymphoma development in castrated males. Although tumor development is delayed in male compared to female mice, sex does not influence tumor immunophenotype, clonality or the frequency of ras mutations in animals given identical MNU treatment protocols. In contrast, the frequency of ras mutations is dramatically altered depending on whether the animals are treated with a single high dose or multiple low doses of MNU. Nevertheless, there is no correlation between the presence of an activated
K-ras
allele and tumor latency. These data demonstrate that sex has a more profound influence on the progression of MNU-induced lymphomas than does the presence of an activated
K-ras
allele.
Carcinogenesis
1994 Oct
PMID:Influence of sex and carcinogen treatment protocol on tumor latency and frequency of K-ras mutations in N-methyl-N-nitrosourea-induced lymphomas. 795 66
This study was undertaken to evaluate the carcinogenic potential of 5-methylchrysene (5-MeC) in strain A/J mouse lung and to correlate the 5-MeC-DNA adduct profile in lung tissue with the mutation spectrum in the
K-ras
gene of lung tumors. Strain A/J mice received a single i.p. injection of 5-MeC at doses of 10, 50, 100 and 200 mg/kg and after 24, 48 and 72 h their lungs were collected for DNA adduct analysis. Eight months later, lungs from the remaining mice were harvested and the lung tumors counted and collected for subsequent mutational analysis of the
K-ras
gene. 5-MeC was found to be a potent lung carcinogen in strain A/J mice, inducing more than 100 tumors/mouse at a concentration of 200 mg/kg. Six 5-MeC-DNA adducts were observed; one adduct comigrated with the standard N2-deoxyguanosine adduct of 5-MeC-diol-epoxide I [1R,2S,3S-trihydroxy-4R-(N2-deoxy-guanosyl-3'-phosphate)- 1,2,3,4-tetrahydro-5-methyl-chrysene], derived from the bay-region diol-epoxide of 5-MeC. DNAs isolated from 5-MeC-induced lung tumors were evaluated for activating mutations in the
K-ras
gene by polymerase chain reaction-single strand conformation polymorphism and direct DNA sequencing analysis. Mutations were detected in 44 of 49 (90%) 5-MeC-induced tumors and the mutations were GGT-->TGT (50%), GGT-->GTT (23%) and GGT-->CGT (27%) in codon 12 of the gene. These results suggest that the N2-deoxyguanosine adduct of 5-MeC-diol-epoxide I may be one of the promutagenic adducts of 5-MeC in strain A/J mouse lung.
Carcinogenesis
1994 Nov
PMID:Tumor multiplicity, DNA adducts and K-ras mutation pattern of 5-methylchrysene in strain A/J mouse lung. 795 14
Dehydroepiandrosterone sulfate (DHEAS) is the most abundant adrenal steroid with apparent anticarcinogenic properties. Given our recent observation of the dehydro-epiandrosterone-mediated inhibition of protein isoprenylation and the fact that 99% of the circulating dehydro-epiandrosterone is sulfated, with less than 1% representing the free steroid, we investigated the effects of DHEAS on post-translational isoprenylation of proteins. We here report that exposure of HT-29 SF human colonic adenocarcinoma cells to DHEAS inhibited the incorporation of [3H]mevalonate into cellular proteins in a dose-dependent manner when endogenous mevalonate synthesis was blocked by lovastatin. Interestingly, significant inhibition was observed at concentrations of DHEAS which are comparable to peak serum levels of this steroid occurring in the second decade of life. Immunoprecipitation revealed that isoprenylation of p21ras was also suppressed in DHEAS-treated HT-29 SF cells. In a cell-free system, DHEAS inhibited the farnesylation of a biotinylated decapeptide corresponding to the C-terminus of
K-ras
by 50% at a concentration of 100 microM. This suggests that DHEAS inhibits isoprenylation of cellular proteins, including p21ras, at a point in the mevalonate pathway distal to 3-hydroxy-3-methylglutaryl-CoA reductase and that the DHEAS-mediated suppression of protein farnesylation may largely be due to inhibition at the level of protein farnesyltransferase. Thus, these findings may provide a plausible explanation for the antitumor activity of DHEAS.
Carcinogenesis
1994 Nov
PMID:Inhibition of protein farnesyltransferase: a possible mechanism of tumor prevention by dehydroepiandrosterone sulfate. 776 95
Treatment of B6C3F1 mice with concentrations of 62.5-625 p.p.m. 1,3-butadiene by inhalation for up to 2 years causes a significantly increased incidence of Harderian gland (HG) neoplasms over untreated controls (Melnick,R., Huff,J., Chou,B.J. and Miller,R.A. Cancer Res., 50, 6592-6599, 1990). Since a specific
K-ras
mutation (codon 13 GGC-->CGC) had previously been described in lung and liver tumors from 1,3-butadiene-treated B6C3F1 mice, we analyzed 23 adenomas and six adenocarcinomas of the HG from mice exposed to 1,3-butadiene for this mutation and mutations in the H-ras gene. We also examined ras activation in 16 spontaneously occurring HG adenomas and one adenocarcinoma. DNA samples were prepared from paraffin-embedded tissues and analyzed by PCR followed by direct sequencing methods. Only one 1,3-butadiene-induced HG tumor contained the
K-ras
codon 13 mutation previously detected in lung and liver tumors. However, 16/29 HG tumors from the treated B6C3F1 mice contained H-ras codon 61 mutations. The mutations detected were: 12 CAA-->CGA transitions, two CAA-->CTA and two CAA-->AAA transversions. Eleven of 17 spontaneous HG tumors contained mutations in H-ras codon 61: five CAA-->CGA transitions, two CAA-->CTA transversions and four CAA-->AAA transversions. While the spectrum of ras mutations did not differ between the spontaneously occurring and chemically induced tumors, these data indicate that activation of H-ras contributes to the process of HG tumorigenesis in both groups of these neoplasms.
Carcinogenesis
1994 Nov
PMID:Activation of H-ras is prevalent in 1,3-butadiene-induced and spontaneously occurring murine Harderian gland tumors. 795 23
We analyzed 15 human pancreatic adenocarcinoma cell lines for alterations of the
K-ras
and the p53 genes and their transcripts. In 11 cell lines (73.3%), point mutations of the
K-ras
gene were found at codon 12 in exon 1. In 9 cell lines one allele was mutated and the other was wild type, and both the alleles were expressed into mRNA. In one cell line both alleles of codon 12 were mutated to TGT and GTT, respectively, but only TGT was transcribed into mRNA. Alterations in mRNA of the p53 gene were detected in 10 cell lines (66.7%). Analysis of the genomic sequence of the p53 gene revealed that the alterations consisted of 6 cases of base pair substitutions and 1 case of 1-bp deletion in evolutionarily conserved exons 5 to 8, 2 cases of splicing mutations in exon 4, and 1 case of novel deletion from exons 2 to 9. In 14 cell lines (93.3%), alterations were identified in the
K-ras
or p53 gene. Of these, 4 cell lines harbored
K-ras
mutations without p53 alteration, whereas 3 cell lines exhibited p53 alterations without
K-ras
mutation. Thus, it is suggested that activation of the
K-ras
gene and inactivation of the p53 gene are strongly and cooperatively associated with pancreatic
carcinogenesis
.
...
PMID:K-ras and p53 alterations in genomic DNA and transcripts of human pancreatic adenocarcinoma cell lines. 796 Nov 2
Mutational activation and overexpression of the family of ras proto-oncogenes have been associated with many human tumors. The role of mutations of H-ras,
K-ras
, and N-ras, as well as expression of the respective protein products (p21s) in normal mucosa, dysplastic mucosa, and squamous cell carcinomas (SCCs) of the head and neck has not been fully described. In our study, 51 tumors (40 paraffin embedded and 11 fresh frozen) were examined to determine if mutational activation of ras is an important molecular event in head and neck SCC. Analyses of codons 12, 13, and 61 of H-ras,
K-ras
, and N-ras revealed no mutations, suggesting that mutational activation of ras is not important in the majority of head and neck SCCs. Immunocytochemistry (ICC) was used to define the expression of H-ras,
K-ras
, and N-ras in normal mucosa, dysplastic mucosa, and SCC of the head and neck and to determine if expression of ras family members correlated with early or late events in the development of SCC. Expression of p21N-ras in nine samples of histologically normal head and neck mucosa revealed moderate staining in the basal proliferative layers with progressively less staining as cells matured. The most superficial layers of normal mucosa failed to express p21N-ras. A low level of p21H-ras was expressed in all layers of normal mucosa while
K-ras
was not expressed. ICC of SCC tumor sections revealed cytoplasmic expression of N-ras in nine of nine tumors, H-ras in five of nine tumors, and
K-ras
in one of nine tumors. Expression of H-ras,
K-ras
, and N-ras in head and neck SCC was not related to histologic differentiation or TNM staging; however, p21N-ras was overexpressed in seven of nine tumors. Furthermore, the pattern of N-ras expression in dysplastic lesions revealed expression in all layers of the mucosa in contrast to normal mucosa, which expresses p21N-ras primarily in the basal proliferative layer. The change in p21N-ras expression pattern in dysplastic mucosa and its overexpression in the majority of tumors suggest that loss of control of N-ras expression may be an early step in
carcinogenesis
of head and neck SCC.
...
PMID:ras mutations and expression in head and neck squamous cell carcinomas. 796 62
The induction of tumors with chemicals and the production of transgenic animals are two experimental approaches to study oncogene involvement in
carcinogenesis
. The combination of both strategies offers an excellent model system to study tumor development. This study analyzes the potential cooperation of N-methylnitrosourea (MNU) treatment and N-ras proto-oncogene overexpression in tumorigenesis in transgenic mice. The overexpression of the N-ras proto-oncogene in these animals is associated with development of mammary tumors and lymphomas. After MNU treatment we analyzed tumor incidence and latency, levels of transgene expression, and pattern of ras mutations in codons 12, 13, and 61 of H-, K-, and N-ras genes in both tumor types. Transgenic mice treated with MNU had significantly (P < 0.001) shorter latency of appearance of mammary tumors [8.6 +/- 3.0 (SD) months] than phosphate-buffered saline-treated transgenics (12.8 +/- 2.3 months). All mammary tumors overexpressed the N-ras transgene and lacked ras mutations. Moreover, MNU-treated transgenics had an incidence and latency of lymphomas similar to that of MNU-treated nontransgenic mice. No significant differences in incidence of point mutations (
K-ras
codon 12 or 13 and N-ras codon 61) in lymphomas were seen between these two groups. All lymphomas overexpressed the N-ras transgene, except for those carrying a
K-ras
point mutation. Overexpression of the N-ras proto-oncogene cooperates with non-ras genes mutated by MNU in mouse mammary
carcinogenesis
. Conversely, N-ras proto-oncogene overexpression does not show cooperation with MNU in lymphomagenesis in our system. This study suggests that proto-oncogene overexpression may be a mechanism of activation of the ras pathway, alternative to point mutation. Similarly to actions for ras genes activated by point mutation, overexpression of the N-ras protooncogene predisposes to tumorigenesis and cooperates with a carcinogen in tumorigenesis. The possibility that ras overexpression plays a role in human breast tumorigenesis requires active investigation.
...
PMID:An overexpressed N-ras proto-oncogene cooperates with N-methylnitrosourea in mouse mammary carcinogenesis. 798 34
In our previous study, we demonstrated that azoxymethane (AOM) treatment significantly enhanced the expression of ras p21, the protein product of ras genes, and that the dietary administration of chemopreventive agents such as D,L-alpha-difluoromethylornithine (DFMO), a irreversible inhibitor of ornithine decarboxylase, and piroxicam, a non-steroidal anti-inflammatory drug (NSAID), exerted a significant inhibitory effect on AOM-induced ras p21 expression. In the present study, which is an extension of our earlier investigation, we have determined the effect of DFMO and piroxicam on mutational activation of ras protooncogenes during AOM-induced colon
carcinogenesis
. Groups of male F344 rats were fed the modified AIN-76A diet containing 0 or 150 p.p.m. piroxicam, or 4000 p.p.m. DFMO and administered s.c. AOM dissolved in normal saline at a dose rate of 15 mg/kg body wt, once weekly, for 4 weeks. Vehicle control groups received s.c. equal volumes of normal saline. Groups of animals were then killed at 0, 4, 16, 24 or 32 weeks after last AOM or saline injection. AOM-induced colon tumors and colonic mucosa from AOM treated as well as saline treated animals were analyzed for point mutations in K- and H-ras protooncogenes by a combination of polymerase chain reaction mediated restriction fragment length polymorphism (PCR-RFLP) and DNA sequencing. Our results demonstrate that of the total 65 AOM-induced colon tumors analyzed, 45/50 (90%) obtained from AOM-treated animals fed the control diet, 4/11 (36%) from AOM-treated animals fed piroxicam diet, and 1/4 (25%) from AOM-treated animals fed the DFMO diet, contained single-point mutations occurring specifically at the second nucleotide of codon 12 which were identified exclusively as G to A transitions in case of
K-ras
, and G to A transitions and also G to T transversions in H-ras. Similar point mutations were identified in colonic mucosa of 21/30 (70%) of AOM-treated animals fed the control diet, 10/30 (33%) of AOM-treated animals fed piroxicam diet, and none of 30 (0%) of AOM-treated animals fed DFMO diet. These results indicate that the administration of piroxicam and DFMO may inhibit the selective amplification of AOM-induced initiated cells carrying mutated ras genes. Dietary DFMO exerted more pronounced inhibition of selective amplification of initiated cells containing AOM-induced mutant ras. Data suggest that determination of ras activation may be a useful marker for chemoprevention of colon cancer.
Carcinogenesis
1994 Jul
PMID:Modulation of azoxymethane-induced mutational activation of ras protooncogenes by chemopreventive agents in colon carcinogenesis. 803 6
6-Nitrochrysene (6-NC), an environmental pollutant and a potent mouse lung carcinogen, is activated by two major metabolic pathways to yield DNA adducts derived from either trans-1,2-dihydro-1,2-dihydroxy-6-aminochrysene (1,2-DHD-6-AC) or N-hydroxy-6-aminochrysene (N-OH-6-AC). While the former pathway has been shown to be the major activation pathway leading to DNA adducts in mice treated with 6-NC, the potential contribution of the minor nitroreduction pathway to tumorigenicity in this system is not clear. To evaluate the roles of these activation pathways and the resulting DNA adducts in mouse lung tumorigenesis, we studied DNA adduct formation, the induction of tumors and tumor
K-ras
mutational spectra in the lungs of male CD-1 mice treated with 6-NC and its metabolites. 6-NC, 6-AC and 1,2-DHD-6-AC produced predominantly a single chromatographically identical dG adduct, and 6-nitrosochrysene (6-NOC) gave a single major adduct that was most likely derived from reaction at the C8 position of deoxyadenosine. 6-NC-, 1,2-DHD-6-AC- and 6-NOC-treated mice developed both adenomas and adenocarcinomas in the lung, whereas only lung adenomas were observed in 6-AC-treated animals.
K-ras
mutations in adenomas resulting from 6-NC and its metabolites were primarily at G:C basepairs in codons 12 and 13, while adenocarcinomas had
K-ras
mutations distributed between codons 12, 13 and 61, and involved both G:C and A:T basepairs. The
K-ras
mutational spectra in codons 12 and 13 were similar in both adenomas and adenocarcinomas whereas a higher percentage of mutations at A:T in codon 61 was found in adenocarcinomas. These results support the conclusion that the 1,2-DHD-6-AC-derived adduct is associated with both adenoma and adenocarcinoma formation and is the primary lesion involved in the induction of mouse lung tumors by 6-NC. The major adduct detected after 6-NOC treatment, which is derived from N-OH-6-AC, is apparently less efficient as an inducer of mouse lung tumors and is associated more specifically with adenocarcinoma formation.
Carcinogenesis
1994 Jul
PMID:Relationships of DNA adduct formation, K-ras activating mutations and tumorigenic activities of 6-nitrochrysene and its metabolites in the lungs of CD-1 mice. 803 14
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