Ataxia telangiectasia (AT) is a rare human autosomal recessive disorder with pleiotropic phenotypes, including neuronal degeneration, immune dysfunction, premature ageing and increased cancer risk. The gene mutated in AT, ATM, encodes a putative lipid or protein kinase. Most of the human AT patient phenotypes are recapitulated in Atm-deficient mice. Cells derived from Atm-/- mice, like those from AT patients, exhibit abnormal response to ionizing radiation. One of the known responses to ionizing radiation is the activation of a nuclear tyrosine kinase encoded by the c-abl proto-oncogene. Ionizing radiation does not activate c-Abl in cells from AT patients or in thymocytes or fibroblasts from the Atm-deficient mice. Ectopic expression of a functional ATM kinase domain corrects this defect, as it phosphorylates the c-Abl tyrosine kinase in vitro at Ser 465, leading to the activation of c-Abl. A mutant c-Abl with Ser 465 changed to Ala 465 is not activated by ionizing radiation or ATM kinase in vivo. These findings identify the c-Abl tyrosine kinase as a downstream target of phosphorylation and activation by the ATM kinase in the cellular response to ionizing radiation.
Sulforaphane-induced G2/M Phase Cell Cycle Arrest Involves Checkpoint Kinase 2-mediated Phosphorylation of Cell Division Cycle 25C
Previously, we showed that sulforaphane (SFN), a naturally occurring cancer chemopreventive agent, effectively inhibits proliferation of PC-3 human prostate cancer cells by causing caspase-9-and caspase-8-mediated apoptosis. Here, we demonstrate that SFN treatment causes an irreversible arrest in the G 2 /M phase of the cell cycle. Cell cycle arrest induced by SFN was associated with a significant decrease in protein levels of cyclin B1, cell division cycle (Cdc) 25B, and Cdc25C, leading to accumulation of Tyr-15-phosphorylated (inactive) cyclin-dependent kinase 1. The SFN-induced decline in Cdc25C protein level was blocked in the presence of proteasome inhibitor lactacystin, but lactacystin did not confer protection against cell cycle arrest. Interestingly, SFN treatment also resulted in a rapid and sustained phosphorylation of Cdc25C at Ser-216, leading to its translocation from the nucleus to the cytoplasm because of increased binding with 14-3-3. Increased Ser-216 phosphorylation of Cdc25C upon treatment with SFN was the result of activation of checkpoint kinase 2 (Chk2), which was associated with Ser-1981 phosphorylation of ataxia telangiectasia-mutated, generation of reactive oxygen species, and Ser-139 phosphorylation of histone H2A.X, a sensitive marker for the presence of DNA double-strand breaks. Transient transfection of PC-3 cells with Chk2-specific small interfering RNA duplexes significantly attenuated SFN-induced G 2 /M arrest. HCT116 human colon cancer-derived Chk2 ؊/؊ cells were significantly more resistant to G 2 /M arrest by SFN compared with the wild type HCT116 cells. These findings indicate that Chk2-mediated phosphorylation of Cdc25C plays a major role in irreversible G 2 /M arrest by SFN. Activation of Chk2 in response to DNA damage is well documented, but the present study is the first published report to link Chk2 activation to cell cycle arrest by an isothiocyanate.Epidemiological studies have revealed an inverse correlation between the dietary intake of cruciferous vegetables and the risk for certain types of cancers, including prostate cancer (1-5). Laboratory studies indicate that the anticancer effect of cruciferous vegetables is caused by isothiocyanates that exist as thioglucoside conjugates (glucosinolates) in a variety of edible plants including broccoli, cabbage, watercress, and so forth (6 -9). Cruciferous vegetable-derived organic isothiocyanates are generated by hydrolytic cleavage of corresponding glucosinolates through catalytic mediation of myrosinases, which are released when the plant cells are damaged because of cutting or chewing (6 -9). Sulforaphane (SFN) 1 is one such isothiocyanate analog that has received a great deal of attention not only because it is present in high concentrations in certain varieties of broccoli but also because of its potent anticancer activity (10 -15). For example, oral administration of SFN (1-isothiocyanato-4-(methylsulfinyl)butane; CH 3 -SO-(CH 2 ) 4 -NϭCϭS)) caused a statistically significant reduction in 9,10-dimethyl-1,2-benzanthr...
Integrin regulation of c-Abl tyrosine kinase activity and cytoplasmic–nuclear transport
The product of the c-abl protooncogene is a nonreceptor tyrosine kinase found in both the cytoplasm and the nucleus. We report herein that cell adhesion regulates the kinase activity and subcellular localization of c-Abl. When fibroblastic cells are detached from the extracellular matrix, kinase activity of both cytoplasmic and nuclear c-Abl decreases, but there is no detectable alteration in the subcellular distribution. Upon adhesion to the extracellular matrix protein fibronectin, a transient recruitment of a subset of c-Abl to early focal contacts is observed coincident with the export of c-Abl from the nucleus to the cytoplasm. The cytoplasmic pool of c-Abl is reactivated within 5 min of adhesion, but the nuclear c-Abl is reactivated after 30 min, correlating closely with its return to the nucleus and suggesting that the active nuclear c-Abl originates in the cytoplasm. In quiescent cells where nuclear c-Abl activity is low, the cytoplasmic c-Abl is similarly regulated by adhesion but the nuclear c-Abl is not activated upon cell attachment. These results show that c-Abl activation requires cell adhesion and that this tyrosine kinase can transmit integrin signals to the nucleus where it may function to integrate adhesion and cell cycle signals.Integrins are heterodimeric transmembrane receptors composed of an ␣ subunit and a  subunit that bind extracellular matrix proteins such as fibronectin (FN) or other cell surface molecules such as the cell adhesion molecules VCAM-1 and ICAM-1 (for review, see ref. 1). Integrin cytoplasmic domains connect to the cytoskeleton to regulate cell spreading, cell migration, and cytoskeletal organization. Integrin-dependent signals are also critical for the adhesion-dependent regulation of gene expression, progression through the cell cycle, and differentiation. These biological effects are mediated through the activation of multiple signal transducers by cell adhesion, in particular tyrosine kinases such as focal adhesion kinase (2) and Src family members (3, 4), mitogen-activated protein (MAP) kinases (5, 6), protein kinase C (7, 8), phosphatidylinositol kinases (9), and the small GTPase Rho (10).The tyrosine kinase encoded by the c-abl protooncogene is found in both the cytoplasm and the nucleus (for review, see ref. 11). It is a multidomain protein containing src homology SH2 and SH3 domains, a tyrosine kinase domain, and binding domains for actin and DNA. The kinase activity of nuclear c-Abl is regulated during cell cycle progression. In quiescent and G 1 cells, nuclear c-Abl is kept in an inactive state by the retinoblastoma protein (RB) that binds to the c-Abl tyrosine kinase domain and inhibits its activity (12, 13). Phosphorylation of RB by cyclin-dependent kinases at the G 1 ͞S boundary disrupts the RB-c-Abl complex, leading to activation of the c-Abl tyrosine kinase. Activated nuclear c-Abl can phosphorylate the C-terminal repeated domain (CTD) of RNA polymerase II to modulate transcription (14, 15). Nuclear c-Abl is part of the RB-E2F complex (16); thus, t...
Genotoxic stress triggers signalling pathways that mediate either the protection or killing of affected cells. Whereas induction of p53 involves events in the cell nucleus, the activation of transcription factors AP-1 and NF-kappaB by ultraviolet radiation is mediated through membrane-associated signalling proteins, ruling out a nuclear signal. An early event in AP-1 induction by ultraviolet radiation is activation of Jun kinases (JNKs), which mediate the induction of the immediate-early genes c-jun and c-fos. The JNKs have also been proposed to mediate the apoptopic response to genotoxins. The non-receptor tyrosine kinase c-Abl is also activated by genotoxic stress. To understand the relationship between these events, we compared the activation of p53, JNK and c-Abl by several DNA-damaging agents in murine fibroblasts. We found that whereas p53 was induced by every genotoxic stimulus tested, c-Abl was activated by most stimuli except ultraviolet irradiation and JNK was strongly stimulated only by ultraviolet light and the alkylating agent methyl methanesulphonate. Activation of JNK by this alkylating agent was normal in c-Abl-null cells but was reduced in c-Src-null cells. Unlike p53 induction, c-Abl activation occurs in the S phase of the cell cycle and does not affect cell proliferation. These findings show that signals generated by genotoxins are transduced by multiple, independent pathways. Only p53 appears to be a universal sensor of genotoxic stress.
The carboxyl-terminal domain (CTD) of the largest subunit of RNA polymerase H is composed of tandem repeats of the consensus sequence Tyr-Ser-Pro-Thr-Ser-ProSer. Phosphorylation of the CTD occurs during formation of the initiation complex and is correlated with the transition from complex assembly to elongation. Previously, serine and threonine residues within the CTD have been shown to be modified by the addition of phosphate and by the addition of 0-linked GlcNAc. Our results establish that the CTD is also modified in vivo by phosphorylation on tyrosine. Furthermore, a nuclear tyrosine kinase encoded by the c-abl protooncogene phosphorylates the CTD to a high stoichiometry in vitro. Under conditions of maximum phosphorylation, =30 mol of phosphate are incorporated per mol of CTD. The observation that the CTD is not phosphorylated by c-Src tyrosine kinase under identical conditions indicates that the CTD is not a substrate of all tyrosine kinases. Phosphorylation of tyrosine residues within the CTD may modulate the interaction of RNA polymerase II with the preinitiation complex and, hence, may be important in regulating gene expression.The largest subunit of eukaryotic RNA polymerase II (RNAP II) contains an unusual carboxyl-terminal domain (CTD) consisting of tandem repeats of a 7-amino acid consensus sequence Tyr-Ser-Pro-Thr-Ser-Pro-Ser (for review, see refs. 1-3). The heptad sequence is repeated 52 times in the CTD of mammalian RNAP II, 42 times in Drosophila, and 26-27 times in yeast (2). Yeast strains with a truncated CTD are temperature sensitive for growth and do not properly express a subset of cellular genes (1, 4). Furthermore, genetic analysis has established that in cultured murine cells at least half the 52 repeats are essential for cell viability (2, 3). In cell-free systems, the CTD is required for transcription from the murine dihydrofolate reductase and several other promoters (3, 5, 6). However, the CTD is dispensable in in vitro transcription from some promoters, including the adenovirus 2 major late and the Drosophila actin SC (3).The CTD is the site of multiple phosphorylations (3). The unphosphorylated RNAP II is designated IIA, and the hyperphosphorylated form is designated IIO. The largest subunit Ila migrates in SDS/PAGE with a molecular mass of 214 kDa, whereas the IIo subunit migrates with an apparent molecular mass of 240 kDa. The mobility shift from IIa to IIo is a direct consequence of CTD phosphorylation (3). The observation that RNAP IIA preferentially associates with the preinitiation complex, whereas transcript elongation is catalyzed by RNAP IIO indicates that CTD phosphorylation occurs after interaction of RNAP II with the promoter but before transcript elongation (3,7,8). Phosphorylation of the CTD has been proposed (3) to trigger the transition from complex assembly to transcript elongation. A number ofThe publication costs of this article were defrayed in part by page charge payment. This article must therefore be hereby marked "advertisement" in accordance with 18...
Defective S-phase checkpoint activation results in an inability to downregulate DNA replication following genotoxic insult such as exposure to ionizing radiation. This 'radioresistant DNA synthesis' (RDS) is a phenotypic hallmark of ataxia-telangiectasia, a cancer-prone disorder caused by mutations in ATM. The mismatch repair system principally corrects nucleotide mismatches that arise during replication. Here we show that the mismatch repair system is required for activation of the S-phase checkpoint in response to ionizing radiation. Cells deficient in mismatch repair proteins showed RDS, and restoration of mismatch repair function restored normal S-phase checkpoint function. Catalytic activation of ATM and ATM-mediated phosphorylation of the protein NBS1 (also called nibrin) occurred independently of mismatch repair. However, ATM-dependent phosphorylation and activation of the checkpoint kinase CHK2 and subsequent degradation of its downstream target, CDC25A, was abrogated in cells lacking mismatch repair. In vitro and in vivo approaches both show that MSH2 binds to CHK2 and that MLH1 associates with ATM. These findings indicate that the mismatch repair complex formed at the sites of DNA damage facilitates the phosphorylation of CHK2 by ATM, and that defects in this mechanism form the molecular basis for the RDS observed in cells deficient in mismatch repair.
Mammalian cells have a remarkable diverse repertoire of response to genotoxic stress that damage DNA. Cellular responses to DNA damaging agents will initially exhibit gene induction, which is regulated by complex mechanism(s) and probably involves multiple signaling pathways. In this paper, we demonstrate that induction of ATF3 protein, a member of the ATF/CREB family of transcription factors, by ionizing radiation (IR) requires normal cellular p53 function. In contrast, induction of ATF3 after UV radiation (UV) or Methyl methanesulphonate (MMS) is independent of p53 status. Induction of ATF3 by DNA damage is rapid, transient, and through a transcriptional mechanism. The ATF3 promoter is induced by UV and MMS, but not by IR. In addition, ATF3 promoter can be activated by MEKK1, an upstream activator of the ERK and JNK kinase pathway, but not induced following p53 expression. Those results indicate that regulation of ATF3 induction after DNA damage utilizes both the p53-dependent andindependent pathways, and may also involve MAP kinase signaling pathways. Using the tetracyclineinducible system (tet-off), we have found that overexpression of ATF3 protein moderately suppresses cell growth. Interestingly, over-expression of ATF3 protein is able to slow down progression of cells from G1 to S phase, indicating that ATF3 protein might play a negative role in the control of cell cycle progression.
In response to DNA damage, the cell cycle checkpoint is an important biological event in maintaining genomic fidelity. Gadd45, a p53-regulated and DNA damage inducible protein, has recently been demonstrated to play a role in the G2-M checkpoint in response to DNA damage. In the current study, we further investigated the biochemical mechanism(s) involved in the GADD45-activated cell cycle G2-M arrest. Using the tetracycline-controlled system (tet-off), we established GADD45-inducible lines in HCT116 (wild-type p53) and Hela (inactivated p53 status) cells. Following inducible expression of the Gadd45 protein, cell growth was strongly suppressed in both HCT116 and Hela cells. Interestingly, HCT116 cells revealed a significant G2-M arrest but Hela cells failed to arrest at the G2-M phases, indicating that the GADD45-activated G2-M arrest requires normal p53 function. The GADD45-induced G2-M arrest was observed independent of p38 kinase activity. Importantly, induction of Gadd45 protein resulted in a reduction of nuclear cyclin B1 protein, whose nuclear localization is critical for the completion of G2-M transition. The reduced nuclear cyclin B1 levels correlated with inhibition of Cdc2/cyclin B1 kinase activity. Additionally, overexpression of cyclin B1 substantially abrogated the GADD45-induced cell growth suppression. Therefore, GADD45 inhibition of Cdc2 kinase activity through alteration of cyclin B1 subcellular localization may be an essential step in the GADD45-induced cell cycle G2-M arrest and growth suppression.
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