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 (ataxia-telangiectasia mutated) is necessary for activation of Chk1 by ATR (ATM and Rad3-related) in response to double-stranded DNA breaks (DSBs) but not to DNA replication stress. TopBP1 has been identified as a direct activator of ATR. We show that ATM regulates Xenopus TopBP1 by phosphorylating Ser-1131 and thereby strongly enhancing association of TopBP1 with ATR. Xenopus egg extracts containing a mutant of TopBP1 that cannot be phosphorylated on Ser-1131 are defective in the ATR-dependent phosphorylation of Chk1 in response to DSBs but not to DNA replication stress. Thus, TopBP1 is critical for the ATM-dependent activation of ATR following production of DSBs in the genome.
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PMID:Ataxia-telangiectasia mutated (ATM)-dependent activation of ATR occurs through phosphorylation of TopBP1 by ATM. 1744 69

ATM, the protein mutated in the human genetic disorder ataxia-telangiectasia, functions by responding to radiation damage to DNA, primarily DNA double strand breaks (dsb), to reduce the risk of genome instability, cancer and neurodegeneration. ATM is rapidly activated as an existing protein to phosphorylate a number of downstream proteins that are involved in DNA repair and cell cycle checkpoint activation. While the exact mechanism of activation of ATM has not been determined, it is now evident that it relies heavily on the Mre11 complex (Mre11/Rad50/Nbs1) and a series of post-translational events for this activation. The Mre11 complex acts as a sensor for the break, recruits ATM to this site where it is autophosphorylated and then is capable of phosphorylating substrates that participate in DNA repair and cell cycle control. A greater understanding of how ATM is activated and functions through different signalling pathways is paramount to devising therapeutic strategies for the treatment of A-T patients. This knowledge can also be used to advantage in sensitizing cells to radiation and ultimately deriving novel therapeutic approaches for the treatment of cancer.
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PMID:DNA damage-induced signalling in ataxia-telangiectasia and related syndromes. 1751 70

Protein kinases control cellular decision processes by phosphorylating specific substrates. Thousands of in vivo phosphorylation sites have been identified, mostly by proteome-wide mapping. However, systematically matching these sites to specific kinases is presently infeasible, due to limited specificity of consensus motifs, and the influence of contextual factors, such as protein scaffolds, localization, and expression, on cellular substrate specificity. We have developed an approach (NetworKIN) that augments motif-based predictions with the network context of kinases and phosphoproteins. The latter provides 60%-80% of the computational capability to assign in vivo substrate specificity. NetworKIN pinpoints kinases responsible for specific phosphorylations and yields a 2.5-fold improvement in the accuracy with which phosphorylation networks can be constructed. Applying this approach to DNA damage signaling, we show that 53BP1 and Rad50 are phosphorylated by CDK1 and ATM, respectively. We describe a scalable strategy to evaluate predictions, which suggests that BCLAF1 is a GSK-3 substrate.
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PMID:Systematic discovery of in vivo phosphorylation networks. 1757 Apr 79

The yeast Mec1/Tel1 kinases, ATM/ATR in mammals, coordinate the DNA damage response by phosphorylating proteins involved in DNA repair and checkpoint pathways. Recently, ATP-dependent chromatin remodeling complexes, such as the INO80 complex, have also been implicated in DNA damage responses, although regulatory mechanisms that direct their function remain unknown. Here, we show that the Ies4 subunit of the INO80 complex is phosphorylated by the Mec1/Tel1 kinases during exposure to DNA-damaging agents. Mutation of Ies4's phosphorylation sites does not significantly affect DNA repair processes, but does influence DNA damage checkpoint responses. Additionally, ies4 phosphorylation mutants are linked to the function of checkpoint regulators, such as the replication checkpoint factors Tof1 and Rad53. These findings establish a chromatin remodeling complex as a functional component in the Mec1/Tel1 DNA damage signaling pathway that modulates checkpoint responses and suggest that posttranslational modification of chromatin remodeling complexes regulates their involvement in distinct processes.
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PMID:Mec1/Tel1 phosphorylation of the INO80 chromatin remodeling complex influences DNA damage checkpoint responses. 1769 58

To ensure survival in the face of genomic insult, cells have evolved complex mechanisms to respond to DNA damage, termed the DNA damage checkpoint. The serine/threonine kinases ataxia telangiectasia-mutated (ATM) and ATM and Rad3-related (ATR) activate checkpoint signaling by phosphorylating substrate proteins at SQ/TQ motifs. Although some ATM/ATR substrates (Chk1, p53) have been identified, the lack of a more complete list of substrates limits current understanding of checkpoint pathways. Here, we use immunoaffinity phosphopeptide isolation coupled with mass spectrometry to identify 570 sites phosphorylated in UV-damaged cells, 498 of which are previously undescribed. Semiquantitative analysis yielded 24 known and 192 previously uncharacterized sites differentially phosphorylated upon UV damage, some of which were confirmed by SILAC, Western blotting, and immunoprecipitation/Western blotting. ATR-specific phosphorylation was investigated by using a Seckel syndrome (ATR mutant) cell line. Together, these results provide a rich resource for further deciphering ATM/ATR signaling and the pathways mediating the DNA damage response.
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PMID:Profiling of UV-induced ATM/ATR signaling pathways. 1807 18

Several DNA damage checkpoint factors form nuclear foci in response to ionizing radiation (IR). Although the number of the initial foci decreases concomitantly with DNA double-strand break repair, some fraction of foci persists. To date, the physiological role of the persistent foci has been poorly understood. Here we examined foci of Ser1981-phosphorylated ATM in normal human diploid cells exposed to 1Gy of X-rays. While the initial foci size was approximately 0.6microm, the one or two of persistent focus (foci) grew, whose diameter reached 1.6microm or more in diameter at 24h after IR. All of the grown persistent foci of phosphorylated ATM colocalized with the persistent foci of Ser139-phosphorylated histone H2AX, MDC1, 53BP1, and NBS1, which also grew similarly. When G0-synchronized normal human cells were released immediately after 1Gy of X-rays and incubated for 24h, the grown large phosphorylated ATM foci (> or =1.6microm) were rarely (av. 0.9%) observed in S phase cells, while smaller foci (<1.6microm) were frequently (av. 45.9%) found. We observed significant phosphorylation of p53 at Ser15 in cells with a single grown phosphorylated ATM focus. Furthermore, persistent inhibition of foci growth of phosphorylated ATM by an ATM inhibitor, KU55933, completely abrogated p53 phosphorylation. Defective growth of the persistent IR-induced foci was observed in primary fibroblasts derived from ataxia-telangiectasia (AT) and Nijmegen breakage syndrome (NBS) patients, which were abnormal in IR-induced G1 checkpoint. These results indicate that the growth of the persistent foci of the DNA damage checkpoint factors plays a pivotal role in G1 arrest, which amplifies G1 checkpoint signals sufficiently for phosphorylating p53 in cells with a limited number of remaining foci.
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PMID:Growth of persistent foci of DNA damage checkpoint factors is essential for amplification of G1 checkpoint signaling. 1824 56

Antibody class switching occurs in mature B cells in response to antigen stimulation and costimulatory signals. It occurs by a unique type of intrachromosomal deletional recombination within special G-rich tandem repeated DNA sequences [called switch, or S, regions located upstream of each of the heavy chain constant (C(H)) region genes, except Cdelta]. The recombination is initiated by the B cell-specific activation-induced cytidine deaminase (AID), which deaminates cytosines in both the donor and acceptor S regions. AID activity converts several dC bases to dU bases in each S region, and the dU bases are then excised by the uracil DNA glycosylase UNG; the resulting abasic sites are nicked by apurinic/apyrimidinic endonuclease (APE). AID attacks both strands of transcriptionally active S regions, but how transcription promotes AID targeting is not entirely clear. Mismatch repair proteins are then involved in converting the resulting single-strand DNA breaks to double-strand breaks with DNA ends appropriate for end-joining recombination. Proteins required for the subsequent S-S recombination include DNA-PK, ATM, Mre11-Rad50-Nbs1, gammaH2AX, 53BP1, Mdc1, and XRCC4-ligase IV. These proteins are important for faithful joining of S regions, and in their absence aberrant recombination and chromosomal translocations involving S regions occur.
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PMID:Mechanism and regulation of class switch recombination. 1837 Sep 22

Human genomic instability syndromes affect the nervous system to different degrees of severity, attesting to the vulnerability of the CNS to perturbations of genomic integrity and the DNA damage response (DDR). Ataxia-telangiectasia (A-T) is a typical genomic instability syndrome whose major characteristic is progressive neuronal degeneration but is also associated with immunodeficiency, cancer predisposition and acute sensitivity to ionizing radiation and radiomimetic chemicals. A-T is caused by loss or inactivation of the ATM protein kinase, which mobilizes the complex, multi-branched cellular response to double strand breaks in the DNA by phosphorylating numerous DDR players. The link between ATM's function in the DDR and the neuronal demise in A-T has been questioned in the past. However, recent studies of the ATM-mediated DDR in neurons suggest that the neurological phenotype in A-T is indeed caused by deficiency in this function, similar to other features of the disease. Still, major issues concerning this phenotype remain open, including the presumed differences between the DDR in post-mitotic neurons and proliferating cells, the nature of the damage that accumulates in the DNA of ATM-deficient neurons under normal life conditions, the mode of death of ATM-deficient neurons, and the lack of a major neuronal phenotype in the mouse model of A-T. A-T remains a prototype disease for the study of the DDR's role in CNS development and maintenance.
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PMID:The neurological phenotype of ataxia-telangiectasia: solving a persistent puzzle. 1845 74

In response to DNA damage, cells activate a signaling pathway that promotes cell cycle arrest and degradation of the cell cycle regulator Cdc25A. Cdc25A degradation occurs via the SCFbeta-TRCP pathway and phosphorylation of Ser-76. Previous work indicates that the checkpoint kinase Checkpoint kinase 1 (Chk1) is capable of phosphorylating Ser-76 in Cdc25A, thereby promoting its degradation. In contrast, other experiments involving overexpression of dominant Chk2 mutant proteins point to a role for Chk2 in Cdc25A degradation. However, loss-of-function studies that implicate Chk2 in Cdc25A turnover are lacking, and there is no evidence that Chk2 is capable of phosphorylating Ser-76 in Cdc25A despite the finding that Chk1 and Chk2 sometimes share overlapping primary specificity. We find that although Chk2 can phosphorylate many of the same sites in Cdc25A that Chk1 phosphorylates, albeit with reduced efficiency, Chk2 is unable to efficiently phosphorylate Ser-76. Consistent with this, Chk2, unlike Chk1, is unable to support SCFbeta-TRCP-mediated ubiquitination of Cdc25A in vitro. In CHK2(-/-) HCT116 cells, the kinetics of Cdc25A degradation in response to ionizing radiation is comparable with that seen in HCT116 cells containing Chk2, indicating that Chk2 is not generally required for timely DNA damage-dependent Cdc25A turnover. In contrast, depletion of Chk1 by RNA interference in CHK2(-/-) cells leads to Cdc25A stabilization in response to ionizing radiation. These data support the idea that Chk1 is the primary signal transducer linking activation of the ATM/ATR kinases to Cdc25A destruction in response to ionizing radiation.
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PMID:Differential roles for checkpoint kinases in DNA damage-dependent degradation of the Cdc25A protein phosphatase. 1848 45

The cellular response to a variety of stress including DNA damage is involved in cell cycle arrest, activation of DNA repair, and in the event of irreparable damage, induction of apoptosis. However, the signals that determine cell fate, that is, survival or apoptosis, are largely unknown. Accumulating studies have revealed that dual-specificity tyrosine-regulated kinases (DYRKs) play key roles on cell proliferation and apoptosis induction. In particular, DYRK2 translocates from the cytoplasm into the nucleus following genotoxic stress. DYRK2 is then activated by ATM and induce apoptosis by phosphorylating p53 at Ser46. Importantly, whereas precise regulation of these kinases remain uncertain, this mechanism has consequences for cell proliferation, differentiation, or apoptosis. This progress review highlights recent efforts demonstrating that DYRKs could be novel and essential regulatory molecules for the regulation of cell fate including apoptosis.
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PMID:Role for DYRK family kinases on regulation of apoptosis. 1859 21

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