Gene/Protein
Disease
Symptom
Drug
Enzyme
Compound
Pivot Concepts:
Gene/Protein
Disease
Symptom
Drug
Enzyme
Compound
Target Concepts:
Gene/Protein
Disease
Symptom
Drug
Enzyme
Compound
Query: UNIPROT:P16104 (
H2AX
)
3,930
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Interferons are cytokines with potent antiviral and antiproliferative activities. We report that although a transient exposure to beta-interferon induces a reversible cell cycle arrest, a sustained treatment triggers a p53-dependent senescence program. Beta-interferon switched on p53 in two steps. First, it induced the acetylation of p53 at lysine 320 and its dephosphorylation at serine 392 but not p53 activity. Later on, it triggered a DNA signaling pathway, the phosphorylation of p53 at serine 15 and its transcriptional activity. In agreement, beta-interferon-treated cells accumulated gamma-
H2AX
foci and phosphorylated forms of ATM and CHK2. The DNA damage signaling pathway was activated by an increase in reactive oxygen species (ROS) induced by interferon and was inhibited by the antioxidant N-acetyl cysteine. More important, RNA interference against ATM inhibited p53 phosphorylation at serine 15, p53 activity and senescence in response to beta-interferon. Beta-interferon-induced senescence was more efficient in cells expressing either, p53, or constitutive allele of
ERK2
or RasV12. Hence, beta-interferon-induced senescence targets preferentially cells with premalignant changes.
...
PMID:DNA damage signaling and p53-dependent senescence after prolonged beta-interferon stimulation. 1643 15
Tumor suppressor p53 protein mediates checkpoint controls and the apoptotic program that are critical for maintaining genomic integrity and preventing tumorigenesis. Forced-induction of MCT-1 decreased p53 expression before and after genomic insults. While inhibiting protein synthesis, the levels of ubiquinated-p53 and the phospho-MDMA2 were significantly increased in ectopic MCT-1 cells. Abrogation of the proteosome degradation process attenuated p53 destabilization and p21 down-regulation by MCT-1. Concomitantly, MCT-1 overexpression enhanced the phosphorylation status of MAPK (ERK1/
ERK2
). While MCT-1 gene knockdown or MEK/ERK pathway inhibition dramatically reduced MAPK phosphorylation, the genotoxin-induced p53 and p21 production were noticeably elevated. Upon Etoposide treatment, ectopic MCT-1 cells relaxed S-phase and G2/M checkpoints followed by G1 phase progressing. Moreover, cells inducing with MCT-1 abridged accumulations of G2/M populations in the response to gamma-irradiation. The polyploidy (DNA content>4N) populations were increased in association with p53 loss in MCT-1 oncogenic cells. Alkaline comet assay validated that ectopic MCT-1 cells were less susceptibility to the genotoxicity. Furthermore, the allocation of nuclear MCT-1 induced by the genotoxic stress was moderately coincided with gamma-
H2AX
appearances. Throughout damage-repairing process, ectopic MCT-1 cells displayed many larger chromosomes and multiple chromosomal fusions compared to the controls that showed increase in chromosomal breaks/gaps and minute chromosomal fragments. Spectral karyotyping analysis precisely identified the acquisition of a single extra copy of chromosome 14 together with a complex genome organizations in ectopic MCT-1 cells, including extra copies of chromosome segments that had been translocated to derivative chromosomes 6 [der(6)] and 9 [der(9)]. In conclusion, MCT-1 deregulates p53-p21 network and impairs the damage checkpoints those are robustly connected to oncogenic chromosomal abnormalities.
...
PMID:MCT-1 oncogene downregulates p53 and destabilizes genome structure in the response to DNA double-strand damage. 1741 11
The MEK-ERK pathway plays a role in DNA damage response (DDR). This has been thoroughly studied by modulating MEK activation. However, much less has been done to directly examine the contributions of ERK1 and
ERK2
kinases to DDR. Etoposide induces G2/M arrest in a variety of cell lines, including MCF7 cells. DNA damage-induced G2/M arrest depends on the activation of the protein kinase ataxia-telangiectasia mutated (ATM). ATM subsequently activates CHK2 by phosphorylating CHK2 threonine 68 (T68) and CHK2 inactivates CDC25C via phosphorylation of its serine 216 (S216), resulting in G2/M arrest. To determine the contribution of ERK1 and
ERK2
to etoposide-induced G2/M arrest, we individually knocked-down ERK1 and
ERK2
in MCF7 cells using specific small interfering RNA (siRNA). Knockdown of either kinases significantly reduced ATM activation in response to etoposide treatment, and thereby attenuated phosphorylation of the ATM substrates, including the S139 of
H2AX
(gammaH2AX), p53 S15, and CHK2 T68. Consistent with these observations, knockdown of either ERK1 or
ERK2
reduced etoposide-induced CDC25C S216 phosphorylation and significantly compromised etoposide-induced G2/M arrest in MCF7 cells. Taken together, we demonstrated that both ERK1 and
ERK2
kinases play a role in etoposide-induced G2/M arrest by facilitating activation of the ATM pathway. These observations suggest that a cellular threshold level of ERK kinase activity is required for the proper checkpoint activation in MCF7 cells.
...
PMID:Both ERK1 and ERK2 kinases promote G2/M arrest in etoposide-treated MCF7 cells by facilitating ATM activation. 2063 59
Modulation of MEK has been demonstrated to affect hydroxyurea (HU) induced-DNA damage response (DDR), implying the involvement of ERK1 and
ERK2
in the process. To directly examine how the ERK kinases function in HU-initiated DDR, we knocked-down either ERK1 or
ERK2
in MCF7 cells. This resulted in reduction of HU-induced phosphorylation of CHK1 S345 (serine 345), p53 S15, and
H2AX
S139. While HU potently induced CDC2 Y15 (tyrosine 15) phosphorylation, an event causing CDC2 inactivation, inhibition of ERK kinases using U0126 (a MEK inhibitor), MEK1K97M (a dominant negative MEK1), and knockdown of either ERK1 or
ERK2
significantly attenuated HU-induced CDC2 Y15 phosphorylation. As CDC2 kinase activity is required for mitosis, our observations reveal that ERK1 and
ERK2
kinases play important roles in preventing mitotic entry in response to HU. Consistent with ATR being the apical kinase to initiate HU-induced DDR, knockdown of ERK1 or
ERK2
significantly inhibited HU-induced ATR recruitment to the stalled replication forks (ATR foci), an event required for ATR activation. Mechanistically, knockdown of ERK1 or
ERK2
resulted in relocation of ATR from the nucleoplasm to the nucleolus in response to HU, therefore making ATR unavailable to the sites of DNA damage. Taken together, we demonstrate that ERK kinases sit upstream of ATR to facilitate its activation.
...
PMID:ERK1 and ERK2 kinases activate hydroxyurea-induced S-phase checkpoint in MCF7 cells by mediating ATR activation. 2084 Aug 67
