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Query: UMLS:C0004135 (
ATM
)
13,001
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
DEAD box proteins are a family of putative RNA helicases associated with all aspects of cellular metabolism involving the modification of RNA secondary structure. DDX1 is a member of the DEAD box protein family that is overexpressed in a subset of retinoblastoma and neuroblastoma cell lines and tumors. DDX1 is found primarily in the nucleus, where it forms two to four large aggregates called DDX1 bodies. Here, we report a rapid redistribution of DDX1 in cells exposed to ionizing radiation, resulting in the formation of numerous foci that colocalize with gamma-H2AX and phosphorylated
ATM
foci at sites of DNA double-strand breaks (DSBs). The formation of DDX1 ionizing-radiation-induced foci (IRIF) is dependent on
ATM
, which was shown to phosphorylate DDX1 both in vitro and in vivo. The treatment of cells with RNase H prevented the formation of DDX1 IRIF, suggesting that DDX1 is recruited to sites of DNA damage containing RNA-DNA structures. We have shown that DDX1 has
RNase
activity toward single-stranded RNA, as well as ADP-dependent RNA-DNA- and RNA-RNA-unwinding activities. We propose that DDX1 plays an RNA clearance role at DSB sites, thereby facilitating the template-guided repair of transcriptionally active regions of the genome.
...
PMID:A role for DEAD box 1 at DNA double-strand breaks. 1871 Sep 41
M059J and M059K cells were isolated from different portions of the same human malignant glioma. M059J cells are more radiosensitive than M059K cells due to the absence of DNA-PKcs and low-expression of
ATM
. The mechanism concerning the absence of DNA-PKcs in M059J is due to the frameshift mutation in PRKDC (DNA-PKcs gene); however, the reason for the low-expression of
ATM
in M059J cells remains unclear. We showed here that the main reason for the lower
ATM
level in M059J cells was not related to the transcriptional regulation or protein degradation but was related to post-transcriptional regulation. Based on database information, we found that the 3'-untranslational region (UTR) of
ATM
contains a miR-100 binding site. By using an
RNase
protection assay and qRT-PCR, we identified that miR-100 is highly-expressed in M059J cells. We further demonstrated that miR-100 bound to the 3'-UTR of
ATM
. Knocking down miR-100 promotes
ATM
expression in M059J cells. Up-regulating miR-100 in M059K cells and other cancer cells reduces
ATM
expression and sensitizes these cells to ionizing radiation. These results indicate that
ATM
is a target of miR-100, elucidating that the low-expression of
ATM
in M059J cells is mainly due to the high expression of miR-100. These results also suggest that miR-100 could be a useful tool to target
ATM
and sensitize tumor cells to ionizing radiation.
...
PMID:Over-expression of miR-100 is responsible for the low-expression of ATM in the human glioma cell line: M059J. 2086 34
Translin-associated protein X (TSNAX), also called trax, was first identified as a protein that interacts with translin. Subsequent studies demonstrated that these proteins form a heteromeric
RNase
complex that mediates degradation of microRNAs, a pivotal finding that has stimulated interest in understanding the role of translin and trax in cell signaling. Recent studies addressing this question have revealed that trax plays key roles in both synaptic plasticity and DNA repair signaling pathways. In the context of synaptic plasticity, trax works together with its partner protein, translin, to degrade a subset of microRNAs. Activation of the translin/trax
RNase
complex reverses microRNA-mediated translational silencing to trigger dendritic protein synthesis critical for synaptic plasticity. In the context of DNA repair, trax binds to and activates
ATM
, a central component of the double-stranded DNA repair process. Thus, these studies focus attention on trax as a critical signaling protein that interacts with multiple partners to impact diverse signaling pathways. To stimulate interest in deciphering the multifaceted role of trax in cell signaling, we summarize the current understanding of trax biology and highlight gaps in our knowledge about this protean protein.
...
PMID:Trax: A versatile signaling protein plays key roles in synaptic plasticity and DNA repair. 3001 97
The RING finger protein TRAIP protects genome integrity and its mutation causes Seckel syndrome. TRAIP encodes a nucleolar protein that migrates to UV-induced DNA lesions via a direct interaction with the DNA replication clamp PCNA. Thus far, mechanistically how UV mobilizes TRAIP from the nucleoli remains unknown. We found that PCNA binding is dispensable for the nucleolus-nucleoplasm shuttling of TRAIP following cell exposure to UV irradiation, and that its redistribution did not rely on the master DNA damage kinases
ATM
and ATR. Interestingly, I-PpoI-induced ribosomal DNA damage led to TRAIP exclusion from the nucleoli, raising the possibility that active ribosomal DNA transcription may underlie TRAIP retention in the nuclear sub-compartments. Accordingly, chemical inhibition of RNA polymerase I activity led to TRAIP diffusion into the nucleoplasm, and was coupled with marked reduction of DNA/RNA hybrids in the nucleoli, suggesting that TRAIP may be sequestered via binding to nucleic acid structures in the nucleoli. Consistently, cell pre-treatment with DNase/
RNase
effectively released TRAIP from the nucleoli. Taken together, our study defines a bipartite mechanism that drives TRAIP trafficking in response to UV damage, and highlights the nucleolus as a stress sensor that contributes to orchestrating DNA damage responses.
...
PMID:Nucleolar residence of the seckel syndrome protein TRAIP is coupled to ribosomal DNA transcription. 3016 63
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