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)

Studies of the roles of oncoproteins in cell cycle progression have concentrated on G1 because transformation is frequently associated with loss of G1 checkpoint control. However, it has become evident that G2 and mitotic checkpoints are often compromised in transformed cells and that many tumour suppressor proteins and oncoprotein kinases regulate and/or are activated in G2 and M. Disruption of p53 and ATM tumour suppressor protein functions can eliminate G2 and M checkpoints. The Src family kinases are activated in mitosis and collectively play an indispensable role in progression through G2/M. In addition, evidence suggests that Mos and elements of the Ras/Raf/MAPK cascade are also active in mitosis and appear likely to regulate G2 and/or M. Potential targets of these kinases include likely regulators of gene expression and microtubule dynamics such as Sam68 and Oncoprotein 18/stathmin. The ability of some oncoproteins to perturb orderly progression through both G1 and/or S and G2 and/or M is probably important for transformation.
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PMID:Oncoprotein signalling and mitosis. 921 24

Sporadic breast carcinoma is associated with multiple genetic alterations. The clinical relevance of these alterations, however, needs further clarification. In the present study we analyzed 266 spontaneously arising breast carcinomas for allelic losses in the BRCA1 and TP53 regions on chromosome 17, the BRCA2 region on chromosome 13, the ATM (mutated in ataxia-telangiectasia) region on chromosome 11 and on the chromosomal arms 7q and 16q. In addition the following clinical and pathological parameters were evaluated: age at diagnosis, tumor size, presence or absence of regional and distant metastases, hormone-receptor status, histopathological classification and tumor grading. The analysis of genetic and clinical observations revealed significant associations: absence of expression of the estrogen receptor was linked to a high rate of allelic losses of markers in the BRCA1, TP53 and BRCA2 regions. Expression of the progesterone receptor coincided with allelic loss on the long arm of chromosome 16. High-grade malignant lesions and ductal differentiation were frequently associated with allelic losses in the proximal portion of chromosome 17q. The accumulation of multiple allelic deletions was linked to high-grade malignant tumors, to tumor size, and to loss of expression of the estrogen receptor. Our data point to a relationship between clinically relevant prognostic factors and specific genomic deletions in the BRCA1, BRCA2 and TP53 region.
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PMID:Genomic deletions in the BRCA1, BRCA2 and TP53 regions associate with low expression of the estrogen receptor in sporadic breast carcinoma. 922 12

The mechanism by which p53 activates apoptosis in various cell systems is unknown. In the absence of an external death stimulus, p53 and p53-dependent genes, bcl-2 and bax, cannot trigger apoptosis. However, p53 may enhance not only transcription of bax and repress bcl-2, but also may upregulate the local renin-angiotensin system, inducing the formation and secretion of angiotensin II from the cells. To test this hypothesis, adult rat ventricular myocytes were infected with AdCMV.p53, which resulted in downregulation of Bcl-2, upregulation of Bax, and death of 34% of the cells. Gel retardation assays demonstrated p53 binding in the promoters of angiotensinogen and angiotensin II AT1 receptor subtype. Angiotensinogen and AT1 mRNAs increased in AdCMV.p53 cells and this phenomenon was associated with a 14-fold increase in the secretion of angiotensin II. The AT1 receptor blocker losartan and angiotensin II antibody prevented p53-induced apoptosis. Thus, p53 enhances the myocyte renin-angiotensin-system and decreases the Bcl-2/Bax ratio in the cells, triggering apoptosis. The identification of this new pathway in p53-mediated apoptosis may be critical in the alterations of myocardial function in the pathologic heart.
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PMID:p53 Induces myocyte apoptosis via the activation of the renin-angiotensin system. 922 70

Mutations in atm and p53 cause the human cancer-associated diseases ataxia-telangiectasia and Li-Fraumeni syndrome, respectively. The two genes are believed to interact in a number of pathways, including regulation of DNA damage-induced cell-cycle checkpoints, apoptosis and radiation sensitivity, and cellular proliferation. Atm-null mice, as well as those null for p53, develop mainly T-cell lymphomas, supporting the view that these genes have similar roles in thymocyte development. To study the interactions of these two genes on an organismal level, we bred mice heterozygous for null alleles of both atm and p53 to produce all genotypic combinations. Mice doubly null for atm and p53 exhibited a dramatic acceleration of tumour formation relative to singly null mice, indicating that both genes collaborate in a significant manner to prevent tumorigenesis. With respect to their roles in apoptosis, loss of atm rendered thymocytes only partly resistant to irradiation-induced apoptosis, whereas additional loss of p53 engendered complete resistance. This implies that the irradiation-induced atm and p53 apoptotic pathways are not completely congruent. Finally-and in contrast to prior predictions-atm and p53 do not appear to interact in acute radiation toxicity, suggesting a separate atm effector pathway for this DNA damage response and having implications for the prognosis and treatment of human tumours.
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PMID:atm and p53 cooperate in apoptosis and suppression of tumorigenesis, but not in resistance to acute radiation toxicity. 924 Dec 81

The functionality of the p53-mediated pathway, activated in response to DNA damage, has been assessed in primary fibroblast cell cultures and Epstein-Barr virus-transformed lymphoblastoid cell lines derived from Nijmegen breakage syndrome (NBS) patients. This autosomal recessive disease is characterized by microcephaly, growth and mental retardation, chromosomal instability, radiosensitivity, and high cancer incidence. The recent mapping of the NBS gene to chromosome 8q21 demonstrates that NBS is genetically distinct from ataxia telangiectasia (AT). Changes in p53 protein levels were significantly reduced and delayed in all the NBS fibroblast cell cultures and lymphoblastoid cell lines examined compared to normal cultures over a 4-h period postirradiation (5 Gy). The transcriptional activation of p21(WAF1/CIP1) mRNA was also lower in 12 NBS fibroblast cultures examined. In agreement with an abrogated p53 function, NBS cells exposed to ionizing radiation show an abnormal cell cycle arrest at G1-S and a prolonged accumulation of cells in the G2 phase. In contrast, exposure to the alkylating agent methyl methanesulfonate results in similar increases of p53 and p21(WAF1/CIP1) mRNA in both cell types. The ATM gene transcript was found to be expressed at similar levels in NBS and normal cells, whereas it was strongly reduced in the AT homozygote cells examined. These results suggest that the ATM gene product cannot substitute for that of the NBS gene in the signaling of cellular damage produced by ionizing radiation and that both are involved in the activation of p53. The suboptimal p53-mediated response could contribute to the high cancer risk and radiosensitivity seen in NBS patients.
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PMID:Nijmegen breakage syndrome cells fail to induce the p53-mediated DNA damage response following exposure to ionizing radiation. 927 79

Ataxia-telangiectasia (A-T) is a recessive multi-system disorder caused by mutations in the ATM gene at 11q22-q23 (ref. 3). The risk of cancer, especially lymphoid neoplasias, is substantially elevated in A-T patients and has long been associated with chromosomal instability. By analysing tumour DNA from patients with sporadic T-cell prolymphocytic leukaemia (T-PLL), a rare clonal malignancy with similarities to a mature T-cell leukaemia seen in A-T, we demonstrate a high frequency of ATM mutations in T-PLL. In marked contrast to the ATM mutation pattern in A-T, the most frequent nucleotide changes in this leukaemia were missense mutations. These clustered in the region corresponding to the kinase domain, which is highly conserved in ATM-related proteins in mouse, yeast and Drosophila. The resulting amino-acid substitutions are predicted to interfere with ATP binding or substrate recognition. Two of seventeen mutated T-PLL samples had a previously reported A-T allele. In contrast, no mutations were detected in the p53 gene, suggesting that this tumour suppressor is not frequently altered in this leukaemia. Occasional missense mutations in ATM were also found in tumour DNA from patients with B-cell non-Hodgkin's lymphomas (B-NHL) and a B-NHL cell line. The evidence of a significant proportion of loss-of-function mutations and a complete absence of the normal copy of ATM in the majority of mutated tumours establishes somatic inactivation of this gene in the pathogenesis of sporadic T-PLL and suggests that ATM acts as a tumour suppressor. As constitutional DNA was not available, a putative hereditary predisposition to T-PLL will require further investigation.
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PMID:Clustering of missense mutations in the ataxia-telangiectasia gene in a sporadic T-cell leukaemia. 928 6

Advances have been made in unravelling the molecular chains of cause and effect that determine cellular responses to radiotherapy, including cell cycle arrest, DNA repair and apoptosis. To begin with, cells must have mechanisms that enable them to sense DNA damage. Little was known about this until recently, when a DNA-protein kinase (DNA-PK) system for detecting radiation-induced strand breaks was described. The ataxia telangiectasia (ATM) gene has amino acid sequence similarities to DNA-PK, raising the possibility that the ATM protein also functions in some way as a sensor of DNA damage. However, just knowing the DNA damage is present is not enough. Signals must be transmitted via afferent biochemical pathways to proteins, such as p53, that determine which cellular responses are activated. The responses include cell cycle arrest, apoptosis and DNA repair, all of which relate closely to loss of clonogenic capacity and the outcome of treatment in our patients.
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PMID:Molecular aspects of cellular responses to radiotherapy. 928 50

Ataxia telangiectasia is a recessive generic disease featuring cerebellar degeneration, developmental abnormalities, high cancer risk, immunodeficiency, and radiosensitivity. Increased levels of unrepaired DNA breaks have been observed in irradiated ataxia telangiectasia cells compared to normal cells but no specific DNA break rejoining rate deficiency has been defined. Alterations in radiation-induced p53-dependent apoptosis have been reported for ataxia telangiectasia cells. This study investigated the radiation response of ataxia telangiectasia lymphoblastoid cells using the comet assay and uncovered a new feature of this technique, namely its capacity to preferentially detect living cells. It is shown here that early after exposure to gamma-rays, ataxia telangiectasia lymphoblasts exhibit an elevated frequency of cells committed to die via apoptosis. The observed apoptosis, which is likely to be independent of p53, leads to a higher number of DNA breaks during the first 3 h post irradiation in ataxia telangiectasia cells, relative to controls. Apart from cells undergoing apoptosis, ataxia telangiectasia lymphoblasts have an identical capacity to rejoin radiation-induced DNA breaks as controls. Results suggest that p53-independent apoptosis may contribute to the radiosensitivity and the immune defects of ataxia telangiectasia patients.
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PMID:Elevated frequency of p53-independent apoptosis after irradiation increases levels of DNA breaks in ataxia telangiectasia lymphoblasts. 929 6

Checkpoint controls arrest cells with defects in DNA replication or DNA damage. For several reasons, checkpoint controls may be relevant to ontogeny and treatment of cancer. Firstly, mutations in two human genes, TP53 and ATM, give rise to cellular defects in cell cycle checkpoints and are associated with cancer. Secondly, although checkpoint defects potentially render the cell damage sensitive, they may do so only in combination with other defects in the cell's response to damage. Therefore, manipulation of checkpoint defects, requiring a description of normal and mutant pathways, will be required for this type of therapeutic approach. Those pathways are being described in yeast cells. In budding yeast, the study of checkpoint genes has led to the view that these genes have many roles in the cellular responses to DNA damage, including roles in arrest in multiple stages of cell cycle, in transcriptional induction of repair genes, in DNA repair itself and additionally some undefined role in DNA replication. The checkpoint pathways and proteins that carry out these responses may consist of sensor proteins that detect damage, signaller proteins that transduce an inhibitory signal and target proteins that are altered to arrest cell division (or cause other changes in cell behaviour). Yeast genes that may act at each step have been identified, leading to a working model of checkpoint pathways. An initial step in the pathway may involve the processing of damage to an intermediate that signals arrest and acts in DNA repair. Human checkpoint pathways may have defects in processing damage as well.
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PMID:Yeast checkpoint controls and relevance to cancer. 933 99

The autosomal recessive disorder ataxia-telangiectasia (AT) is highly pleiotropic. It is characterized by gradual loss of Purkinje cells in the cerebellum, leading to progressive neuromotor deterioration, immunodeficiency, developmental defects in specific tissues, profound predisposition to malignancy and acute sensitivity to ionizing radiation. AT cells show chromosomal instability, premature senesence, radiosensitivity and defects in cell cycle checkpoints activated by ionizing radiation. Several radiation induced pathways that regulate the cell cycle seem to be defective in AT cells, at least one of which is mediated by TP53. Extensive characterization of the cellular defects of AT cells, together with the recent isolation of the ATM gene, has provided some insight into the possible physiological roles of the ATM protein. Several lines of evidence, including the nature of the agents that elicit the hypersensitivity of AT cells, point to the possibility of a defect in the response to damage induced by oxidative stress, which affects various cellular macromolecules. The ATM protein might have a role in activating defence mechanisms against oxidative stress. This hypothesis broadens the previous concept of the AT defect and explains several aspects of the AT phenotype that cannot be accounted for by defective processing of DNA damage.
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PMID:The ATM gene and protein: possible roles in genome surveillance, checkpoint controls and cellular defence against oxidative stress. 933 5

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