Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UMLS:C0004135 (ATM)
 13,001 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

We have previously demonstrated that cells from patients with ataxia-telangiectasia (A-T) fail to show initial delay at several cell cycle checkpoints post-irradiation. In addition a defect in the induction of p53 by ionizing radiation was evident. We demonstrate here that the radiation signal transduction pathway operating through p53, its target gene WAF1, cyclin-dependent kinases and the retinoblastoma (Rb) protein is defective in A-T cells. The defective p53 induction after ionizing radiation, observed previously in A-T cells, was also reflected at the functional level using p53-DNA binding activity, transactivation and transfection with wild type p53. Correction of the defect at the G1/S checkpoint was observed when wild type p53 was constitutively expressed in A-T cells. Exposure of control cells to radiation gave rise to p53 induction and as a consequence increased expression of WAF1 mRNA and protein, but A-T cells were defective in this response. As expected the WAF1 response in irradiated control cells resulted in an inhibition of cyclin-dependent kinase activity including cyclin E-cdk2, which plays an important role in the transition from G1 to S phase. No inhibition of cyclin-dependent kinase activity was observed in A-T cells correlating with the delayed WAF1 response. On the contrary an enhancement of cyclin-dependent kinase activity was seen in A-T cells post-irradiation. An accumulation of the hypophosphorylated form of Rb protein occurred in irradiated control cells compatible with the G1/S phase delay observed in these cells after exposure to radiation. In unirradiated A-T cells the amount of Rb protein was much higher compared to controls and it was mainly in the hyperphosphorylated (functionally inactive) form. In addition, accumulation of the hypophosphorylated form of Rb in A-T cells post-irradiation was defective, consistent with the lack of cell cycle arrest. Thus the failure of the G1/S checkpoint in A-T cells after exposure to ionizing radiation is consistent with a defective radiation signal transduction pathway operating through p53.
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PMID:Nature of G1/S cell cycle checkpoint defect in ataxia-telangiectasia. 765 23

The early events in the G2 checkpoint response to ionizing radiation (IR) were analyzed in diploid normal human fibroblasts (NHFs) and fibroblasts from patients with two heritable cancer syndromes. Exposure to gamma-radiation of asynchronously growing NHFs resulted in a rapid reduction in the number of cells in mitosis (G2 delay) and was accompanied by a quantitatively similar reduction in the p34CDC2/cyclin B in vitro histone H1 kinase activity as compared with sham-treated controls. This G2 delay was strong by 1 h following exposure to IR, maximal by 2 h, and was accompanied by an accumulation of tyrosine-phosphorylated p34CDC2 molecules. In contrast, fibroblasts from individuals with ataxia telangiectasia displayed significantly less reduction of the mitotic index or histone H1 kinase activity after IR. Low passage fibroblasts from individuals with Li-Fraumeni syndrome having one wild-type and one mutated p53 allele were similar to NHFs in their immediate G2 checkpoint response to IR, as were NHFs expressing the human papilloma virus type 16 E6 gene product (functionally inactivating p53) and low passage cells from p53-deficient mouse embryos. However, the p53-deficient fibroblasts were genomically unstable and became defective in their early G2 checkpoint response to IR. Furthermore, immortal Li-Fraumeni syndrome fibroblasts lacking wild-type p53 displayed an attenuated G2 checkpoint response. These results link the early events in G2 checkpoint response to IR in NHFs with a rapid inhibition of p34CDC2/cyclin B protein kinase activity and demonstrate that while not required for this immediate G2 delay, lack of p53 can lead to subsequent genetic alterations that result in defective G2 checkpoint function.
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PMID:Defective G2 checkpoint function in cells from individuals with familial cancer syndromes. 771 86

The recent description of a novel gene (ATM) mutated in ataxia-telangiectasia (A-T), with homologies to genes encoding proteins involved in both G1/S and G2/M checkpoint control, points to a common defect in cell cycle control in A-T operating through the cyclin-dependent kinases. In this report we demonstrate that cyclin-dependent kinases are resistant to inhibition by ionizing radiation exposure in A-T cells, and this appears to be due to insufficient induction of WAF1. Exposure of control lymphoblastoid cells to radiation during S phase and in G2 phase causes a rapid inhibition of cyclin A-Cdk2 and cyclin B-Cdc2 activities, respectively. Irradiation led to a 5-20-fold increase in Cdk-associated WAF1 in these cells, which accounts at least in part for the decrease in cyclin-dependent kinase activity. In contrast, radiation did not inhibit any of the cyclin-dependent kinase activities in S phase or G2 phase in A-T cells at short times after irradiation nor was there any significant change in the level of Cdk-associated WAF1 compared to unirradiated cells. These results are similar to those reported previously for the G1 checkpoint and provide additional evidence for the involvement of ATM at multiple points in cell cycle regulation.
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PMID:Defect in multiple cell cycle checkpoints in ataxia-telangiectasia postirradiation. 870 89

Ataxia telangiectasia (AT) is an autosomal recessive disease of unknown etiology associated with cerebellar ataxia, oculocutaneous telangiectasia, immunodeficiency, and hypersensitivity to ionizing radiation. Although AT has been divided into four complementation groups by its radioresistant-DNA synthesis phenotype, the ATM gene has been isolated as the candidate gene responsible for all AT groups. We identified a new gene, designated NPAT, from the major AT locus on human chromosome 11q22-q23. The gene encoded a 1421-amino-acid protein containing nuclear localization signals and phosphorylation target sites by cyclin-dependent protein kinases associated with E2F. The messenger RNA of NPAT was detected in all human tissues examined, and its genomic sequence was strongly conserved through eukaryotes, suggesting that the NPAT gene may be essential for cell maintenance and may be a member of the housekeeping genes. Analysis of the genomic region of NPAT surprisingly revealed that the gene existed only 0.5 kb apart from the 5' end of the ATM transcript with opposite transcriptional direction. It may be possible to propose the idea that the promoter region could be shared by both housekeeping genes and that each gene could influence the expression of the other.
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PMID:Identification and characterization of a new gene physically linked to the ATM gene. 874 93

Angiotensin II (Ang II) induces hypertrophy of cultured proximal tubular epithelial cells including the LLC-PK1 cell line. We have previously shown that this hypertrophy appears in the G1-phase of the cell cycle. Since progression through the cell cycle is controlled by a series of cyclin and cyclin-dependent kinase (CdK) complexes that may be inactivated by CdK inhibitors, we studied the expression of the CdK-inhibitor p27Kip1 in LLC-PK1 cells challenged with Ang II. Compared to cells grown in serum-free medium, Ang II treatment enhanced p27Kip1 protein, but not mRNA expression. This p27Kip1 induction was mediated through AT1-receptors. Exogenous TGF-beta also stimulated p27Kip1 protein expression. Immunoprecipitation experiments revealed that p27Kip1 preferentially associated with CdK4 in Ang II-treated LLC-PK1 cells and that the activity of this kinase was inhibited after Ang II-treatment, an effect that may be generated by increased p27Kip1 binding to cyclin D1-CdK4 complexes. In contrast, p27Kip1 was not associated with cyclin E-CdK2 complexes in Ang II-stimulated cells. Treatment of LLC-PK1 cells with p27Kip1 antisense, but not missense, oligonucleotides abolished the Ang II-mediated cell hypertrophy as measured by de novo protein synthesis and total protein content, and facilitated entry into the S-phase of the cell cycle. Our findings suggest that Ang II stimulates p27Kip1 expression in renal cells. Furthermore, this induction of the CdK-inhibitor appears pivotal in the hypertrophy induced by Ang II and elucidates the molecular mechanisms associated with this growth response in proximal tubular cells.
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PMID:Angiotensin II-stimulated hypertrophy of LLC-PK1 cells depends on the induction of the cyclin-dependent kinase inhibitor p27Kip1. 894 98

Cellular processes leading to renal tubular hypertrophy may contribute to the development of progressive renal disease. Angiotensin II (ANG II) is a prime agent that has been linked to the progression of renal disease by a host of mechanisms, including the induction of tubular epithelial hypertrophy and stimulation of extracellular matrix biosynthesis. All components of a functional renin-angiotensin system reside within the renal tubule. Epithelial cells exhibit distinct patterns of growth behavior after stimulation with ANG II (namely, hypertrophy of proximal tubule segments and proliferation of more distal segments). The hypertrophic action of ANG II is mediated through high-affinity AT1-receptors, involves activation of pertussis-toxin sensitive G1 proteins, and depends on a decrease in intracellular cAMP. In addition, ANG II induces sequential activation of MAP kinases and S6 kinase, and leads to activation of early immediate genes and the modulation of a series of cyclins and cyclin-dependent kinases. There is also compelling evidence that the ANG II-induced epithelial hypertrophy and the stimulated-synthesis of collagen type IV are mediated by increased transcription and production of TGF-beta. ANG II-mediated inhibition of protein degradation may further increase protein content. The hypertrophic response to ANG II is greater in medium with high glucose concentration. Blockade of the action of ANG II prevents the renal hypertrophy and the tubulointerstitial fibrosis in animal models of chronic renal diseases (independent of changes in systemic or glomerular hemodynamics), in part through interception of ANG II-mediated induction of TGF-beta expression.
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PMID:Renal tubular hypertrophy induced by angiotensin II. 931 13

Ataxia telangiectasia (AT) is an autosomal recessive disorder characterized by growth retardation, cerebellar ataxia, oculocutaneous telangiectasias, and a high incidence of lymphomas and leukemias. In addition, AT patients are sensitive to ionizing radiation. Atm-deficient mice recapitulate most of the AT phenotype. p21(cip1/waf1 )(p21 hereafter), an inhibitor of cyclin-dependent kinases, has been implicated in cellular senescence and response to gamma-radiation-induced DNA damage. To study the role of p21 in ATM-mediated signal transduction pathways, we examined the combined effect of the genetic loss of atm and p21 on growth control, radiation sensitivity, and tumorigenesis. As might have been expected, our data provide evidence that p21 modifies the in vitro senescent response seen in AT fibroblasts. Further, it is a downstream effector of ATM-mediated growth control. In addition, however, we find that loss of p21 in the context of an atm-deficient mouse leads to a delay in thymic lymphomagenesis and an increase in acute radiation sensitivity in vivo (the latter principally because of effects on the gut epithelium). Modification of these two crucial aspects of the ATM phenotype can be related to an apparent increase in spontaneous apoptosis seen in tumor cells and in the irradiated intestinal epithelium of mice doubly null for atm and p21. Thus, loss of p21 seems to contribute to tumor suppression by a mechanism that operates via a sensitized apoptotic response. These results have implications for cancer therapy in general and AT patients in particular.
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PMID:Loss of p21 increases sensitivity to ionizing radiation and delays the onset of lymphoma in atm-deficient mice. 940 57

We investigated the requirements for protein p53 and the ATM gene product in radiation-induced inhibition of DNA synthesis and regulation of the cyclin E/ and cyclin A/cyclin dependent kinases (Cdks). Wild type (WT) mouse lung fibroblasts (MLFs), p53(-/-) knock-out MLFs, normal human skin fibroblasts (HSF-55), and human AT skin fibroblasts (GM02052) were used in the investigations. The absence of p53 had no significant effect on the inhibition or recovery of DNA synthesis throughout the S phase, as determined from BrdU labeling and flow cytometry, or the rapid inhibition of cyclin A/Cdks. Gamma radiation (8 Gy) inhibited DNA synthesis and progression into G2 during the first 3 h after irradiation, and the recovery of these processes occurred at similar rates in both WT and p53(-/-) MLFs. The cyclin A/Cdks were inhibited 55-70% at 1 h after irradiation in both cell types, but p21WAF1/Cip1 levels or p21 interaction with Cdk2 did not increase in the irradiated p53(-/-) MLFs. Although p53(-/-) MLFs do not exhibit prolonged arrest at a G1 checkpoint, radiation did induce a rapid 20% reduction and small super-recovery of cyclin E/Cdk2 within 1-2 h after irradiation. Similar inhibition and recovery of cyclin E/Cdk2 previously had been associated with regulation of transient G1 delay and the inhibition of initiation at an apparent G1/S checkpoint in Chinese hamster cells. In contrast, loss of the ATM gene product abrogated transient cyclin E/Cdk2 inhibition, most inhibition of DNA synthesis and all, but a 10-15% inhibition, of the cyclin A/Cdks. The results indicate that neither p53 nor p21 is required for transient inhibition of cyclin E/Cdk2 associated with the G1/S checkpoint or for inhibition of DNA synthesis at 'checkpoints' within the S phase. Conversely, the ATM gene product appears to be essential for regulation of the G1/S checkpoint and for inhibition of DNA replication associated with the inhibition of cyclin A/Cdk2. Differential aspects of DNA synthesis inhibition among cell types are presented and discussed in the context of S phase checkpoints.
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PMID:Requirements for p53 and the ATM gene product in the regulation of G1/S and S phase checkpoints. 948 36

Three DNA damage-responsive cell cycle checkpoints can be shown to operate in diploid human fibroblasts. One checkpoint arrests growth in G1, another inhibits replicon initiation in S phase cells, and the third delays progression from G2 into mitosis. Progression from G2 into M is controlled in part by a cyclin-dependent kinase (cyclin B/Cdk1) that is regulated by tyrosine phosphorylation. Phosphorylation of Tyr15 on Cdk1 is inhibitory for kinase activity. Activation of cyclin B/Cdk1 at the onset of mitosis is accomplished by a phosphatase, Cdc25C, that interacts with cyclin B/Cdk1 in an autocatalytic feedback loop to remove the inhibitory phosphate at Tyr15 and activate kinase activity. DNA damage triggers G2 delay by inhibiting formation of the autocatalytic feedback loop so that dephosphorylation of Tyr15 does not occur. This suppression of activation of cyclin B/Cdk1 appears to account for the failure of damaged G2 cells to progress into mitosis. Once the damage to DNA is repaired, cells resume progression into mitosis as the cycle is re-engaged. The isoflavone genistein inhibits tyrosine kinases, including one that phosphorylates Cdk1 on Tyr15. This kinase, p56/p53lyn is rapidly induced by treatments that trigger cell cycle checkpoints (ionizing radiation, cytosine arabinoside), suggesting that this kinase may actively delay the onset of mitosis by phosphorylating Tyr15 on Cdk1. Genistein also inhibits type II DNA topoisomerase to produce a form of DNA damage that triggers all of the DNA damage-responsive cell cycle checkpoints. A brief 10 min incubation with the topoisomerase poison amsacrine was sufficient to trigger the S phase checkpoint response and inhibit replicon initiation. Inhibition of replicon initiation by 1 microM amsacrine was maximal 20-30 min after drug treatment and by 120 min, the checkpoint response had decayed to allow near control rates of replicon initiation. Topoisomerase II poisons also are powerful clastogens inducing lethal and carcinogenic chromosomal aberrations. Type II topoisomerase can break DNA in a region of chromosome 11q23 that contains the ataxia telangiectasia gene (ATM). The ATM gene controls all of the DNA damage-responsive cell cycle checkpoints. Chromosomal aberrations in 11q23 are frequently seen in acute myeloid leukemia that develops as a consequence of etoposide chemotherapy. Thus, topoisomerase poisons such as genistein may trigger chromatid breakage to inactivate AT gene function, disable cell cycle control, and induce genetic instability.
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PMID:Human topoisomerase II function, tyrosine phosphorylation and cell cycle checkpoints. 949 43

Initiation of DNA replication during the mitotic cell cycle requires the activation of a cyclin-dependent protein kinase (CDK). The B-type cyclins Clb5 and Clb6 are the primary activators of the S phase function of the budding yeast CDK Cdc28. However, in mitotically growing cells this role can be fulfilled by the other B-type cyclins Clb1-Clb4. We report here that cells undergoing meiotic development also require Clb dependent CDK activity for DNA replication. Diploid clb5/clb5 clb6/clb6 mutants are unable to perform premeiotic DNA replication. Despite this defect, the mutant cells progress into the meiotic program and undergo lethal segregation of unreplicated DNA suggesting that they fail to activate a checkpoint that restrains meiotic M phase until DNA replication is complete. We have found that a DNA replication checkpoint dependent on the ATM homolog MEC1 operates in wild-type cells during meiosis and can be invoked in response to inhibition of DNA synthesis. Although cells that lack clb5 and clb6 are unable to activate the meiotic DNA replication checkpoint, they do possess an intact DNA damage checkpoint which can restrain chromosome segregation in the face of DNA damage. We conclude that CLB5 and CLB6 are essential for premeiotic DNA replication and, consequently, for activation of a meiotic DNA replication checkpoint.
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PMID:CLB5 and CLB6 are required for premeiotic DNA replication and activation of the meiotic S/M checkpoint. 973 68


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