UMLS:C0001430 - FACTA Search

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Query: UMLS:C0001430 (adenoma)
21,222 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Using polymerase chain reaction and sequence-specific oligonucleotide hybridization, the frequency of three ras oncogene mutations (N-ras, Ha-ras, and K-ras) in thyroid tumors (25 adenomas, 16 follicular carcinomas, and 22 papillary carcinomas) was investigated in both iodide-deficient and iodide-sufficient areas. The ras oncogene mutation rate was significantly higher in the iodide-deficient area, being 85 versus 17% in the adenomas, and 50 versus 10% in the follicular carcinomas. No mutations were found in papillary carcinomas. The most common mutation site was Ha-ras codon 61 with Gln----Arg substitution. Two ras mutations at codon 61 (Gln----Lys in N-ras and Gln----Arg in Ha-ras) were found in a microfollicular adenoma specimen from Eastern Hungary. We conclude that dietary iodine may modulate ras oncogene mutations, and that in the iodide-deficient area, ras oncogene activation may play a more important role in the initiation and/or maintenance of follicular tumors. Additional factors are, however, necessary to initiate carcinogenesis.
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PMID:High rates of ras codon 61 mutation in thyroid tumors in an iodide-deficient area. 202 46

Remarkable advances in the understanding of specific inherited and acquired genetic events that are important in colonic carcinogenesis have occurred in the last several years. Studies of the population genetics of colon cancer have determined that the gene responsible for familial adenomatous polyposis (FAP), and Gardner's syndrome has been localized on the long arm of chromosome 5 and have more clearly defined the importance of genetic influences in 'sporadic' colon cancer. Studies of the molecular genetics of colon cancer have identified acquired alterations in oncogenes such as the K-ras gene and in putative tumor suppressor genes such as the FAP gene on chromosome 5, the p53 gene on chromosome 17, and the DCC gene on chromosome 18, which appear to mediate important steps in the adenoma-dysplasia-carcinoma sequence. Some of these research advances (FAP gene carriage) are already being used clinically to identify individuals at risk for colon cancer, and they offer great promise for the future of both prevention and therapeutic programs.
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PMID:Lessons from the genetics of colon cancer. 217 30

Structural alterations of protooncogene sequences may be involved in the pathogenesis of human neoplasms. We screened 54 thyroid tumors (36 benign and 18 malignant) for gene rearrangements of the protooncogenes c-myc, c-myb, c-fos, c-erb-B1, c-erb-B2, c-erb-A, N-ras, K-ras, and H-ras. Only mutations of H-ras were observed. None of the 15 colloid adenomas examined had detectable H-ras rearrangements. Of the remaining tumors, we observed mutations of H-ras in 4 benign and 4 malignant neoplasms. Gene amplification was found in 5 tumors. An aggressive recurrent papillary carcinoma had a marked amplification of one of the H-ras alleles. The amplified allele was truncated, in that the 3' variable tandem repeat was not a part of the amplification unit, and contained a codon 12 point mutation leading to a valine for glycine substitution. We also observed the association of low copy gene amplification with a codon 12 valine for glycine mutation in a follicular adenoma. Two tumors contained H-ras EcoRI polymorphisms not present in the DNA of normal thyroid from the same individuals, and one follicular carcinoma showed loss of an H-ras allele. Ras protooncogenes may become transforming by quantitative mutations, leading to increased expression, or qualitative mechanisms, through activating point mutations. Both of these appear to coexist in thyroid neoplasms, and it may be that a combination of both mechanisms is capable of inducing a more complete spectrum of neoplastic phenotypes.
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PMID:H-ras protooncogene mutations in human thyroid neoplasms. 219 80

We analyzed genomic DNA from 43 sporadic benign parathyroid adenomas for rearrangements of the PTH gene, and for point mutations of the H-ras (codons 12, 13, and 61), N-ras (codons 12, 13, and 61), and K-ras (codons 12 and 13) genes. One of 43 parathyroid adenomas showed a chromosome 11 rearrangement involving both the PTH gene on the short arm of chromosome 11 (at band p15) and a locus on the long arm (11q13). This rearrangement was indistinguishable from one that was previously described in a parathyroid adenoma by Arnold et al., indicating that this may be an important contributor to tumorigenesis in a small subset of patients with parathyroid adenoma. H-ras, K-ras, and N-ras oncogene activation by point mutation at codons 12, 13, or 61, known to occur in many tumors, could not be detected in any parathyroid adenoma.
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PMID:Genetic abnormalities in sporadic parathyroid adenomas. 219 77

Using an in vitro amplification step (polymerase chain reaction) followed by oligonucleotide dot blot analysis, DNA samples from 29 familial polyposis coli patients (75 polyp-derived and 26 'normal' colon samples with no epithelial atypia) were screened for the presence of K-, N-, and H-ras mutations. Only 5 polyps contained ras mutations (7%)--all in K-ras codon 12. In each case 'normal' colon DNA was available and found to be negative in this assay. We also report the detection of K-ras codon 12 mutations in a stably non-tumorigenic immortal adenoma-derived cell line, PC/AA, and in a tumorigenic colorectal carcinoma cell line, PC/JW. Both epithelial cell lines were derived from different FPC patients. An activated K-ras gene was also found in cell line S/AN, isolated from a sporadic villous adenoma. These results provide further evidence that there are common molecular events involved in sporadic and hereditary colorectal carcinogenesis and that K-ras mutations can precede the development of malignancy. To our knowledge PC/AA is the first reported example of a human cell line bearing a mutant ras gene that is not tumorigenic and shows that the presence of an activated ras gene even in an immortal human cell line is insufficient for malignancy.
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PMID:A study of ras gene mutations in colonic adenomas from familial polyposis coli patients. 257 69

Fischer 344/Ncr rats of both sexes were subjected to partial hepatectomy and then initiated 21-24 h later by a single injection of methyl(acetoxymethyl)nitrosamine at 0.1 mmol/kg body weight via the portal vein. Beginning 3 weeks later, development of hepatocellular neoplasms in initiated rats was promoted by feeding 0.05% phenobarbital (PB) in the diet. Not only intrahepatic lesions but also a variety of extrahepatic tumors were induced. High-molecular-weight DNAs were prepared from 67 samples of grossly normal liver containing multiple preneoplastic foci/areas of microscopic dimensions, 137 hepatocellular adenomas (nodules), 93 hepatocellular carcinomas (HCC), 10 cholangiomas, and 25 extrahepatic tumors in 95 rats and tested for transforming activity in the NIH 3T3 transfection assay. DNA preparations from 7 of 93 HCCs, 2 of 10 cholangiomas, 2 of 137 nodules, 1 histiocytic sarcoma, and 1 thyroid carcinoma were positive in the transfection assay. Southern blot analysis showed that NIH 3T3 transformants induced by DNA from 5 HCCs, 1 hepatocellular adenoma, 1 cholangioma, 1 histiocytic sarcoma, and 1 thyroid carcinoma contained an activated K-ras gene of rat origin. Rat-derived H-ras was identified in transformants from 2 additional HCCs and rat c-raf from 1 hepatocellular adenoma. The transforming gene from one cholangioma showed no sequence homology to the ras genes, neu, or c-raf. Immunoprecipitation analysis of ras Mr 21,000 protein in 11 transformants indicated that, based upon protein electrophoretic mobilities, activation of the ras genes consistently resulted from mutations in codon 12 of these genes. Selective oligonucleotide analysis revealed that a G----A transition in the second base of codon 12 of K-ras was present in the 9 K-ras-positive transformants and also in DNAs prepared from the original tumors. In contrast, oligonucleotide hybridization experiments with DNAs from 35 hepatocellular tumors that were negative in transfection assays revealed the presence of mutant K-ras in 1 of 15 HCCs; no mutation could be detected in 20 transfection-negative adenomas. The infrequency of detection of a specific oncogene, more frequent detection of oncogenes in malignant tumors, and failure to observe activated oncogenes in preneoplastic lesions suggest that activation of ras oncogenes may occur as a late and infrequent event in the evolution of some rat hepatocellular neoplasms and that mutation of a specific ras locus is not an obligatory early event in the genesis of these neoplasms.
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PMID:Infrequent activation of K-ras, H-ras, and other oncogenes in hepatocellular neoplasms initiated by methyl(acetoxymethyl)nitrosamine, a methylating agent, and promoted by phenobarbital in F344 rats. 264 46

Neoplastic progression of colorectal epithelial cells from benign adenomas to malignant carcinomas appears to result from a series of genetic alterations involving both oncogenes and tumor suppressor genes. This progression was recently found to be associated with expression of splice variant isoforms of CD44, a cell surface hyaluronate receptor implicated in carcinogenesis. In this study we examined the relationship of CD44 expression to somatic genetic events in the adenoma-carcinoma sequence: point mutation of K-ras in codons 12 and 13 and overexpression of p53 protein as a marker of gene mutation. Among 22 small adenomas, CD44 was present in 9 (41%), of which only 1 contained a K-ras mutation. CD44 was absent in the other 2 small adenomas positive for K-ras mutation or p53 overexpression. In contrast to the early expression of CD44 in small adenomas, mutations of K-ras and p53 were detected preferentially in large adenomas and late-stage adenomas containing carcinoma. The frequent expression of CD44 prior to K-ras and p53 gene alterations in colorectal neoplasia suggests that activation of CD44 gene expression is related to earlier events in the adenoma-carcinoma sequence, possibly cell activation and proliferation following APC gene mutation or alteration of DNA methylation.
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PMID:CD44 expression in colorectal adenomas is an early event occurring prior to K-ras and p53 gene mutation. 751 84

Focal neoplastic change occurs frequently within the colorectum. Yet, of the several hundreds of microadenomas that are likely to be present within an individual colorectum, only one or two will develop into a clinically diagnosable adenoma. In turn, only a fraction of adenomas will progress to malignancy. The risk that a particular microadenoma will end its natural history as a carcinoma varies according to clinical context. The risk is very low in familial adenomatous polyposis (FAP), but relatively high in hereditary non-polyposis colorectal cancer (HNPCC). This variation is governed by the timing and ordering of the underlying mutational events. In FAP, inactivation of the wild-type APC gene occurs early, whereas K-ras mutations are late events. The converse appears to apply in the case of sporadic adenomas. In flat adenomas, which are known to be relatively aggressive, K-ras mutations may not occur at all. In HNPCC, mutational events are accelerated as a result of defective DNA mismatch repair. The evolution of colorectal adenoma occurs through a variety of quite distinct genetic pathways.
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PMID:Colorectal adenoma progression and genetic change: is there a link? 754 18

Colorectal cancer affect the 15% of general population in developed countries. Cancer is a multistep process in which multiple genetic alterations must usually occur in several years. The premalignant step consists of one or multiple aberrant crypts due to hyperproliferation of cells and its shift from the deep third of the crypt to its surface. It has been suggested that abnormality in the APC gene is responsible for this. Furthermore, there exists DNA hypometilation, activation of the gene K-ras and ornithine decarboxylase activity. There is also a loss of MCC gene, that seems to interact with the APC gene. Entire alterations described make possible the Class I adenoma formation. This adenoma, needs the loss of the DCC gene (late stage in the carcinogenesis process), to become a Class II adenoma. The following alteration is deleted and mutation of the p53 gene. There is also an activation of the c-myc oncogene. These two genes are important mechanisms for the conversion of a benign adenoma to a malignant one, adenoma with in situ carcinoma or Class III adenoma. This type of adenoma becomes carcinoma and metastatic stage, throughout inactivation of several tumor suppressor genes. Besides the hereditary APC alteration and other acquired genetic changes as described above there are other associated genetics, antigenics, and enzymes that have an important role in the adenoma-carcinoma sequence. Several carcinogenic factors have been described which also contribute in the adenoma and carcinoma formation: ulcerative colitis, acromegaly, familial history of colonic neoplasia, certain professions, smoking and drinking, consumption of red or processed meat, etc.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:[Etiology of colorectal cancer]. 755 83

We studied 43 thyroid tumors including 5 adenomatous goiters, 7 follicular adenomas, 22 papillary carcinomas, and 9 medullary carcinomas with regard to the presence of point mutations in the genes of Gs alpha subunit (Gs alpha), Gi2 alpha subunit (Gi2 alpha), H-ras, K-ras, and N-ras by a polymerase chain reaction-direct sequencing method. An adenomatous goiter and a follicular adenoma showed double mutations at codon 227 and 231, and 4 papillary carcinomas showed mutation at codon 231 of the Gs alpha gene. An adenomatous goiter, a follicular adenoma, and a papillary carcinoma showed a missense mutation in codon 13 of the K-ras gene. There were no such missense mutations of these G-protein or ras genes in medullary carcinomas. These data indicate that the genetic events involved in the oncogenesis of parafollicular C-cells are different from those of thyroid follicular cells, in which missense mutations of Gs alpha and ras genes seem to play important roles in tumorigenesis.
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PMID:Point mutations of ras and Gs alpha subunit genes in thyroid tumors. 755 96

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