UMLS:C0004135 - FACTA Search

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Query: UMLS:C0004135 (ATM)
13,001 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

ATM, the gene product mutated in the cancer susceptibility syndrome ataxia-telangiectasia, is related to proteins involved in DNA repair and cell-cycle control, perhaps explaining how ATM prevents carcinogenesis.
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PMID:Cancer predisposition. Ataxia-telangiectasia at the crossroads. 857 69

Ataxia telangiectasia (AT) is a genetic disorder with an autosomic recessive transmission. Occurring during childhood, it affects different organs and/or systems. Physiopathology is still unclear. The first clinical signs are evident early in childhood and evolution always leads to death. The secondary cause of mortality in 10 to 15% of the affected is the development of cancers. Genetic predisposition to cancer for homozygotes, as well as for heterozygotes, is one of the most remarkable aspects of this disease. For heterozygotes the risk of cancer is three times that of the norm. The gene responsible for the disease has been cloned. Its function may resolve some questions, and provide the link between degenerative process, cancer susceptibility and immunodeficiency evident in AT patients.
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PMID:[Ataxia telangiectasia and genetic predisposition to cancer]. 869 18

Ataxia-telangiectasia (A-T) is a multisystem recessive disease characterized clinically by cerebellar ataxia, oculocutaneous telangiectasias, immunodeficiency, sensitivity to radiomimetic agents, and cancer predisposition. This pleiotropic disorder is caused by mutations in the ATM (mutated in A-T) gene, which is located in the human chromosomal region 11q22-q23. The ATM gene product is a member of a novel family of large proteins implicated in the regulation of the cell cycle and response to DNA damage. Heterozygosity for A-T was previously suggested to be associated with an increased risk of tumors, particularly female breast cancer. Because of loss of constitutional heterozygosity at 11q22-q23 is a frequent event in breast and other tumors, suggesting the presence of a tumor suppressor gene(s) in this region, we screened blood DNA samples from 88 unrelated breast cancer patients of Swedish cancer families for ATM mutations using single-strand conformation polymorphism analysis. All patients had a family history of tumors previously associated with A-T heterozygosity or homozygosity. We demonstrate the first three germ-line mutations in ATM identified by screening of breast cancer patients. Two mutations were previously found in A-T homozygotes and one mutation was a 1-bp insertion. All mutations were found in families with a large number of tumors, however, they did not cosegregate with malignancies. Although the proportion of A-T carriers in this sample seems to be higher than expected by chance, larger studies and pooled data sets will be required to establish that an A-T allele confers cancer susceptibility in heterozygotes.
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PMID:ATM mutations in cancer families. 879 79

This study describes a correlation between cellular DNA repair capacity and the frequency of mutagen-induced in vitro chromosomal breaks in selected lymphoblastoid cell lines. Two assays, host cell reactivation (HCR) assay for measuring cellular DNA repair capacity and in vitro mutagen sensitivity assay, have recently been shown to be useful biomarkers for such susceptibility. Increased in vitro mutagen sensitivity, measured by the number of induced chromatid breaks, has been postulated to reflect decreased capacity of DNA repair, as measured by the HCR assay. However, these two assays have not been examined in parallel to test this hypothesis. In this study, we performed both assays in 16 established lymphoblastoid cell lines derived from patients with xeroderma pigmentosum (n = 3), ataxia telangiectasia (n = 2), head and neck cancer (n = 3), and melanoma (n = 2), and from normal human subjects (n = 6) using UV light, 4-nitroquinoline-1-oxide (4-NQO; an UV-mimetic agent), and gamma-irradiation as the test agents. The measurements from the HCR assay correlated significantly with the frequency of chromatid breaks induced by either UV irradiation (r = -0.69; P < 0.01) or 4-NQO (r = -0.70; P < 0.01). Although published data suggest that damage induced by UV and 4-NQO may be repaired by different pathways, the two agents induced similar frequencies of chromatid breaks (r = 0.68; P < 0.01) in the tested cell lines. Our results also indicated that the HCR assay is not suitable to test agents that cause DNA strand breaks, such as gamma-irradiation, whereas the mutagen sensitivity assay is. Although reduced cellular DNA repair capacity correlated with increased frequency of mutagen-induced chromatid breaks in these cell lines, these two assays have different sensitivities in measuring the repair of damage induced by different carcinogens; therefore, the use of both assays is recommended for future molecular epidemiological studies of cancer susceptibility.
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PMID:DNA repair capacity correlates with mutagen sensitivity in lymphoblastoid cell lines. 883 20

Breast cancer is the most common form of cancer in women in the U.S. The risk factors for developing breast cancer include increasing age, a family history of breast cancer, and the lack of a child by age 30. A substantial fraction of breast cancer, however, occurs in women who have no identifiable risk factors. The diagnosis, pathology, treatment, and presymptomatic testing of cancer susceptibility genes are reviewed. Syndromes with an associated risk of breast cancer are described, such as hereditary breast-ovarian cancer syndrome, Li-Fraumeni syndrome, ataxia telangiectasia, and Cowden's disease. With the localization of the BRCA1 gene to chromosome 17q21 and the BRCA2 gene to chromosome 13q12, issues surrounding breast cancer susceptibility genetic testing are assuming an ever greater measure of importance. The sensitivity and specificity for molecular testing of cancer susceptibility genes, however, have not been well defined. The progress in presymptomatic genetic testing is further hampered by various factors such as the technical difficulty in distinguishing mutations from polymorphisms, the number of different mutations identified thus far and the possibility of false positive and false negative results. Laboratory quality assurance/quality control issues are of paramount importance to avoid misleading interpretations. Many issues surrounding genetic screening and testing, such as insurance and employment discrimination, privacy, and informed consent, are under active debate, and guidelines and standards are under active development. It is therefore important to proceed with caution, so that irreversible harm resulting from data misinterpretation can be avoided.
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PMID:Clinical and research issues in breast cancer genetics. 887 57

Breast cancer is the most common malignancy among women. Genetic predisposition is considered to account for 5-10% of all cases while the majority of these cancers are sporadic and caused by complex interactions of exogenous and endogenous factors. The inherited predisposition can be due to germline mutations in one of several cancer susceptibility genes. For high risk families the two most important genes are BRCA1 on chromosome 17q, which confers a high risk of both, breast and ovarian cancer and BRCA2 on chromosome 13 associated with high penetrance of breast cancer but lower risk of ovarian cancer. A high risk of breast cancer is conferred by mutations in the p53 tumor suppressor gene as part of the rare Li-Fraumeni-syndrome, and possibly also by the estrogen receptor gene. Other cancer genes associated with a less increased risk of breast cancer are the autosomal recessive ataxia telangiectasia (AT) gene and the HRAS1 gene. Germline mutations in BRCA1 and BRCA2 account for the majority of families with multiple cases of breast and/or ovarian cancer and also at least 10% of cases below the age of 40 years. Genetic testing for BRCA1 mutations is not generally recommended except for women with a strong family history. The aim for the management of familial breast cancer should be the establishment of interdisciplinary teams to cover genetic counseling, molecular analysis, onco-surgical therapy, psychosocial support and clinical follow-up.
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PMID:[Molecular genetics of hereditary breast carcinoma]. 917 60

Certain growth regulatory kinases contain a common domain related to the phospho-inositol 3 (PI-3) kinase catalytic site. These include the ATM gene product, DNA-PKcs, and the target of rapamycin (TOR in yeast; and FRAP in mammalian cells). Rapamycin inhibits growth factor signalling and induces G1 arrest in many cell types. Some growth regulatory PI-3 kinases appear functionally linked to p53 and we have explored potential links between cellular effects induced by rapamycin and p53. In p53 null cells rapamycin inhibited cell cycling but did not induce G1 arrest. In cells which showed selective G1 arrest in response to rapamycin, rapamycin had no effect on basal levels of p53 protein. Similarly p21(WAF1) protein was not induced by rapamycin. The kinetics of the cellular p53/p21(WAF1) response to ionising radiation was unaffected by rapamycin; and the ability of growth factor to protect against p53-mediated apoptosis in response to DNA damage was also unaffected by rapamycin. The ATM gene is mutated in the cancer susceptibility syndrome ataxia telangiectasia (AT) but such mutant cells showed a similar sensitivity to rapamycin compared to their normal counterparts. RKO cell lines of common genetic background, but with different levels of functional p53 protein, also responded similarly to rapamycin. Thus, although rapamycin and p53 are each able to induce G1 arrest, they appear to act through independent growth regulatory pathways.
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PMID:Rapamycin and p53 act on different pathways to induce G1 arrest in mammalian cells. 934 96

Both p53 and ATM are checkpoint regulators with roles in genetic stabilization and cancer susceptibility. ATM appears to function in the same DNA damage checkpoint pathway as p53. However, ATM's role in p53-dependent apoptosis and tumor suppression in response to cell cycle dysregulation is unknown. In this study, we tested the role of murine ataxia telangiectasia protein (Atm) in a transgenic mouse brain tumor model in which p53-mediated apoptosis results in tumor suppression. These p53-mediated activities are induced by tissue-specific inactivation of pRb family proteins by a truncated simian virus 40 large T antigen in brain epithelium. We show that p53-dependent apoptosis, transactivation, and tumor suppression are unaffected by Atm deficiency, suggesting that signaling in the DNA damage pathway is distinct from that in the oncogene-induced pathway. In addition, we show that Atm deficiency has no overall effect on tumor growth and progression in this model.
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PMID:Atm is dispensable for p53 apoptosis and tumor suppression triggered by cell cycle dysfunction. 1008 76

Ataxia telangiectasia (AT) carrier-derived lymphoblastoid cell lines (AT-LCLs/hetero) with suboptimal ATM protein expression were examined for the regulation of radiosensitivity, apoptosis, and mitotic spindle checkpoint in response to DNA-damaging agents. Although AT-LCLs/hetero showed intermediate radiation sensitivity, as determined by clonogenic assay, they were resistant to early-onset apoptosis, as much as AT patient-derived LCLs (AT-LCLs/homo). Furthermore, two of three AT-LCLs/hetero showed defective mitotic spindle checkpoint control in response to X-ray irradiation, which is a recently characterized biological feature in AT-LCLs/homo. Our findings indicate that carriers of ATM mutation have biological abnormalities due to haploinsufficiency of ATM protein or dominant-negative effect of mutant ATM protein. Thus, although it is still controversial whether ATM mutation carriers are at higher risk for cancer during adulthood, our findings based on in vitro biological indicators support the notion that at least some of such carriers are at a higher risk for cancer development than those without ATM mutation. Our findings may help to reevaluate epidemiological studies on cancer susceptibility in AT carriers.
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PMID:Defective control of apoptosis and mitotic spindle checkpoint in heterozygous carriers of ATM mutations. 1036 81

The failure to find an increased frequency of ATM mutations in large cancer cohorts, especially breast cancer, is contrary to what was anticipated based on the increased cancer susceptibility of obligate ATM heterozygotes from families with ataxia-telangiectasia (A-T). We hypothesize that this paradox might be resolved if two types of ATM heterozygotes exist and the phenotypes differ, i.e., those with truncating types of mutations (ATM(trunc)), that make no protein, and those with missense types of mutations (ATM(mis)), that make reduced amounts of defective protein. The phenotype of ATM(trunc/trunc) mutations is the A-T syndrome; the phenotype of ATM(mis/mis) mutations, judging from the few homozygous patients that have been documented, appears to include some neurological features and cancer susceptibility but not the A-T syndrome. Evidence is reviewed which suggests that ATM(mis/wt) mutations are technically more difficult to detect than ATM(trunc/wt) mutations. Despite this, most large cancer cohort studies have identified mainly missense mutations and few truncating mutations. This model would require a paradigm shift for cancer risk analyses, to recognize the existence of different allele frequencies for the two types of A-T heterozygotes.
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PMID:Cancer risk in ATM heterozygotes: a model of phenotypic and mechanistic differences between missense and truncating mutations. 1060 71

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