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Query: UNIPROT:P43146 (
tumour suppressor
)
5,935
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Dissection of germline mutations in a sensitive and specific manner presents a continuing challenge. In dominantly inherited diseases, mutations occur in only one allele and are often masked by the normal allele. Here we report the development of a sensitive and specific diagnostic strategy based on somatic cell hybridization termed MAMA (monoallelic mutation analysis). We have demonstrated the utility of this strategy in two different hereditary colorectal cancer syndromes, one caused by a defective
tumour suppressor
gene on chromosome 5 (familial adenomatous polyposis, FAP) and the other caused by a defective mismatch repair gene on chromosome 2 (hereditary non-polyposis colorectal cancer,
HNPCC
).
...
PMID:Monoallelic mutation analysis (MAMA) for identifying germline mutations. 755 Mar 26
The purpose of this review is to analyze the role of genetic factors in the pathogenesis of human cancer, with particular attention to tumours of the digestive organs. Human neoplasms are defined as "sporadic" when there is no evidence of cancer among relatives besides the index case; "Familial" tumours are characterized by cancer aggregation in a given family, but without verticality or other features of mendelian (autosomal) transmission. In "Hereditary" tumours there is sufficient clinical and biologic evidence to suspect that genetic factors are the main event responsible for their development. Hereditary tumours have been associated with germ-line mutations of oncogenes or, more often, of
tumour suppressor
genes. More recently, a new category of cancer-related genes has been defined-the mutator genes-which are involved in the mechanisms of DNA repair. Among the various hereditary cancer syndromes, Hereditary non polyposis Colorectal Cancer (
HNPCC
or Lynch syndrome), Familial Adenomatous Polyposis (FAP) and related syndromes, Hereditary Breast tumours, Li-Fraumeni syndrome and Von Hippel-Lindau disease have been discussed in more detail. Besides purely scientific problems, many ethical and social aspects remain to be solved in hereditary cancer syndromes, and it is likely that their solution will require-in the years to come-a close collaboration between oncologists, geneticists and basic research workers.
...
PMID:Genetic basis of tumour development. 884 41
The discovery of powerful mutator phenotypes in a subset of colon cancers provides direct support for the hypothesis that destabilization of replication fidelity and repair drive the accumulation of mutations in
tumour suppressor
or proto-oncogenes. Nevertheless, many important questions remain. The tumour cell lines in which these mutator genes were characterized have many other mutations that may contribute to the mutator phenotype and the characteristic pattern of mutations found in these cells. Thus, mismatch repair deficiency may be necessary for the mutator phenotype, but is it sufficient? Certainly, changes in DNA replication fidelity or cell cycle checkpoint controls may contribute to the mutator phenotype. This question also has important implications for the effect of mismatch repair deficiency on tumour development. Does the mutator phenotype in
HNPCC
patients arise as a very early event resulting from the loss of the wild type allele or does it arise in later stages only after alterations of cell cycle controls or replication fidelity? Given that eukaryotic cells have numerous homologues of the mismatch repair genes, what are the roles of all these genes? Are these involved in the repair of very specific types of replication errors or do they have other roles in cells? Finally, what mechanisms underlie the accumulation of mutations in other types of tumours? Given the rapid progress made since the isolation of the human homologues of the E coli mismatch repair genes less than 3 years ago, we can look forward to the answers to many of these questions in the near future.
...
PMID:Patterns of mutation in cancer cells. 897 27
DNA methylation plays an important part in the regulation of gene expression. Alterations in DNA methylation in tumours have been reported and have been used to generate hypotheses about mutagenesis and silencing of
tumour suppressor
genes. However, the underlying mechanism is still poorly understood, and conflicting data on the levels of overexpression of 5'-cytosine DNA methyltransferase in sporadic colon carcinoma have been published. We used a competitive RT-PCR assay for quantification of mRNA of 5'-cytosine DNA methyltransferase in colon biopsies obtained from patients with hereditary colon carcinoma syndromes and compared the results with those obtained in a control group. No significant difference was found between the flat mucosa of FAP patients and the mucosa of the control group. In FAP and
HNPCC
patients, the 5'-cytosine DNA methyltransferase mRNA levels of adenomas were significantly higher (P<0.05) than of flat mucosa in the same group, but both showed great variability from patient to patient. Our findings suggest that the mRNA levels of methyltransferase cannot be used as predictive marker for screening in families affected by hereditary colon carcinoma.
...
PMID:5'-Cytosine DNA-methyltransferase mRNA levels in hereditary colon carcinoma. 1007 Dec 36
About 5% of colorectal cancer cases are due to an autosomal dominant genetic predisposition with high penetrance. In this condition, the patient is carrier of a pathogenic gene mutation present in all body cells which can be transmitted to descendants, a so-called germ line mutation. The mutation is usually present in a
tumour suppressor
gene. Three subgroups of hereditary colorectal cancer can be distinguished on the basis of the clinical characteristics: (a) syndromes without polyposis (mostly hereditary non-polyposis colorectal carcinoma;
HNPCC
), (b) syndromes with adenomatous polyposis (mostly familial adenomatous polyposis; FAP) and (c) syndromes with hamartomatous polyposis. Recently, the main gene defects which underlie these syndromes were identified. Consequently, it is possible in approximately half the families with
HNPCC
or FAP in patients with colorectal cancer to demonstrate the causative gene defect and subsequently, by blood testing of healthy relatives to determine who is and is not a carrier of this hereditary condition. Thus, preventive measures can be directed toward family members with a demonstrable high risk of large bowel cancer.
...
PMID:[Genetics of colorectal cancer. I. Non-polyposis and polyposis forms of hereditary colorectal cancer]. 1038 34
HNPCC
(Hereditary non-polyposis colorectal cancers) development is caused by mutation of genes included in system of mismatch repair genes. The mutation exists at 60% of patients in hMSH2 gene, 30% in hMLH1 and 10% both in hPMS1and hPMS2 genes. RER+ exists in about 90% in hereditary non-polyposis colorectal cancer and about 15-28% in sporadic cancers. The purpose of the study was to determine highly sensitive microsatellite markers which can be fast and efficient way of microsatellite screening for detection of
HNPCC
patients. Moreover, we have analysed the loss of heterozygosity of
tumour suppressor
genes which could have the diagnostic value in detection of HPNCC patients.
...
PMID:Molecular analysis: microsatellity instability and loss of heterozygosity of tumor suppressor gene in hereditary non-polyposis colorectal cancers (HNPCC). 1928 89
