ATM and the Mre11-Rad50-Nbs1 complex respond to nucleoside analogue-induced stalled replication forks and contribute to drug resistance

The Mre11-Rad50-Nbs1 complex and autophosphorylated Ser(1981)-ATM are involved in recognizing and repairing DNA damage, such as double-strand breaks (DSB). However, the role of these factors in response to stalled replication forks is not clear. Nucleoside analogues are agents that are incorporated into DNA during replication, which cause stalling of replication forks. The molecular mechanisms that sense these events may signal for DNA repair and contribute to survival but are poorly understood. Cellular responses to both DSBs and stalled replication forks are marked by H2AX phosphorylation on Ser(139) (gamma-H2AX), which forms nuclear foci at sites of DNA damage. Here, concentrations of the nucleoside analogues 1-beta-d-arabinofuranosylcytosine (cytarabine; ara-C), gemcitabine, and troxacitabine, which inhibited DNA synthesis by 90% within 2 hours, were determined for each agent. Using gamma-H2AX as a marker for changes in chromatin structure, we show that Mre11, Rad50, Nbs1, and phosphorylated ATM respond to nucleoside analogue-induced stalled replication forks by forming nuclear foci that colocalize with gamma-H2AX within 2 hours. Because neither DSBs nor single-strand breaks were detectable after nucleoside analogue exposure, we conclude that this molecular response is not due to the presence of DNA breaks. Deficiencies in ATM, Mre11, or Rad50 led to a 2- to 5-fold increase in clonogenic sensitization to gemcitabine, whereas Nbs1 and H2AX deficiency did not affect reproductive growth. Taken together, these results suggest that ATM, Mre11, and Rad50 are required for survival after replication fork stalling, whereas Nbs1 and H2AX are inconsequential.     

Suppression of Tousled-like kinase activity after DNA damage or replication block requires ATM,NBS1 and Chk1

The human Tousled-like kinases 1 and 2 (TLK) have been shown to be active during S phase of the cell cycle. TLK activity is rapidly suppressed by DNA damage and by inhibitors of replication. Here we report that the signal transduction pathway, which leads to transient suppression of TLK activity after the induction of double-strand breaks (DSBs) in the DNA, is dependent on the presence of a functional ataxia-telangiectasia-mutated kinase (ATM). Interestingly, we have discovered that rapid suppression of TLK activity after low doses of ultraviolet (UV) irradiation or aphidicolin-induced replication block is also ATM-dependent. The nature of the signal that triggers ATM-dependent downregulation of TLK activity after UVC and replication block remains unknown, but it is not due exclusively to DSBs in the DNA. We also demonstrate that TLK suppression is dependent on the presence of a functional Nijmegan Breakage Syndrome protein (NBS1). ATM-dependent phosphorylation of NBS1 is required for the suppression of TLK activity, indicating a role for NBS1 as an adaptor or scaffold in the ATM/TLK pathway. ATM does not phosphorylate TLK directly to regulate its activity, but Chk1 does phosphorylate TLK1 GST-fusion proteins in vitro. Using Chk1 siRNAs, we show that Chk1 is essential for the suppression of TLK activity after replication block, but that ATR, Chk2 and BRCA1 are dispensable for TLK suppression. Overall, we propose that ATM activation is not linked solely to DSBs and that ATM participates in initiating signaling pathways in response to replication block and UV-induced DNA damage.     

Chk1 phosphorylation of Metnase enhances DNA repair but inhibits replication fork restart

Chk1 both arrests replication forks and enhances repair of DNA damage by phosphorylating downstream effectors. Although there has been a concerted effort to identify effectors of Chk1 activity, underlying mechanisms of effector action are still being identified. Metnase (also called SETMAR) is a SET and transposase domain protein that promotes both DNA double-strand break (DSB) repair and restart of stalled replication forks. In this study, we show that Metnase is phosphorylated only on Ser495 (S495) in vivo in response to DNA damage by ionizing radiation. Chk1 is the major mediator of this phosphorylation event. We had previously shown that wild-type (wt) Metnase associates with chromatin near DSBs and methylates histone H3 Lys36. Here we show that a Ser495Ala (S495A) Metnase mutant, which is not phosphorylated by Chk1, is defective in DSB-induced chromatin association. The S495A mutant also fails to enhance repair of an induced DSB when compared with wt Metnase. Interestingly, the S495A mutant demonstrated increased restart of stalled replication forks compared with wt Metnase. Thus, phosphorylation of Metnase S495 differentiates between these two functions, enhancing DSB repair and repressing replication fork restart. In summary, these data lend insight into the mechanism by which Chk1 enhances repair of DNA damage while at the same time repressing stalled replication fork restart.     

Ataxia-telangiectasia-mutated dependent phosphorylation of Artemis in response to DNA damage

Artemis plays a crucial role in the hairpin-opening step of antigen receptor VDJ gene recombination in the presence of catalytic subunit of deoxyribonucleic acid (DNA)-dependent protein kinase (DNA-PKcs). A defect in Artemis causes human radiosensitive-severe combined immunodeficiency. Cells from Artemis-deficient patients and mice display increased chromosomal instability, but the precise function of this factor in the response to DNA damage remains to be elucidate. In this study, we show that Artemis is hyperphosphorylated in an Ataxia-telangiectasia-mutated (ATM)- and Nijmegen breakage syndrome 1 (Nbs1)-dependent manner in response to ionizing radiation (IR), and that S645 is an SQ/TQ site that contributes to retarded mobility of Artemis upon IR. The hyperphosphorylation of Artemis is markedly reduced in ATM- and Nbs1-null cells. Reintroduction of wild-type ATM or Nbs1 reconstituted Artemis hyperphosphorylation in ATM- or Nbs1-deficient cells, respectively. In support of this functional link, hyperphosphorylated Artemis was found to physically associate with the Mre11/Rad50/Nbs1 complex in an ATM-dependent manner in response to IR-induced DNA double strand breaks (DSB). Since deficiency of either DNA-Pkcs or ATM leads to defective repair of IR-induced DSB, our finding places Artemis at the signaling crossroads downstream of DNA-PKcs and ATM in IR-induced DSB repair.     

ATM is required for the repair of Topotecan-induced replication-associated double-strand breaks

Purpose

DNA replication is a promising target for anti-cancer therapies. Therefore, the understanding of replication-associated DNA repair mechanisms is of great interest. One key factor of DNA double-strand break (DSB) repair is the PIK kinase Ataxia-Telangiectasia Mutated (ATM) but it is still unclear whether ATM is involved in the repair of replication-associated DSBs. Here, we focused on the involvement of ATM in homology-directed repair (HDR) of indirect DSBs associated with replication.

Material and methods

Experiments were performed using ATM-deficient and -proficient human cells. Replication-associated DSBs were induced with Topotecan (TPT) and compared with γ-irradiation (IR). Cell survival was measured by clonogenic assay. Overall DSB repair and HDR were evaluated by detecting residual γH2AX/53BP1 and Rad51 foci, respectively. Cell cycle distribution was analysed by flow cytometry and protein expression by Western blot.

Results

ATM-deficiency leads to enhanced numbers of residual DSBs, resulting in a pronounced S/G2-block and decreased survival upon TPT-treatment. In common with IR, persisting Rad51 foci were detected following TPT-treatment.

Conclusions

These results demonstrate that ATM is essentially required for the completion of HR-mediated repair of TPT-induced DSBs formed indirectly at replication forks.     

The orally active and bioavailable ATR kinase inhibitor AZD6738 potentiates the anti-tumor effects of cisplatin to resolve ATM-deficient non-small cell lung cancer in vivo

ATR and ATM are DNA damage signaling kinases that phosphorylate several thousand substrates. ATR kinase activity is increased at damaged replication forks and resected DNA double-strand breaks (DSBs). ATM kinase activity is increased at DSBs. ATM has been widely studied since ataxia telangiectasia individuals who express no ATM protein are the most radiosensitive patients identified. Since ATM is not an essential protein, it is widely believed that ATM kinase inhibitors will be well-tolerated in the clinic. ATR has been widely studied, but advances have been complicated by the finding that ATR is an essential protein and it is widely believed that ATR kinase inhibitors will be toxic in the clinic. We describe AZD6738, an orally active and bioavailable ATR kinase inhibitor. AZD6738 induces cell death and senescence in non-small cell lung cancer (NSCLC) cell lines. AZD6738 potentiates the cytotoxicity of cisplatin and gemcitabine in NSCLC cell lines with intact ATM kinase signaling, and potently synergizes with cisplatin in ATM-deficient NSCLC cells. In contrast to expectations, daily administration of AZD6738 and ATR kinase inhibition for 14 consecutive days is tolerated in mice and enhances the therapeutic efficacy of cisplatin in xenograft models. Remarkably, the combination of cisplatin and AZD6738 resolves ATM-deficient lung cancer xenografts.     

Hypoxia-induced phosphorylation of Chk2 in an ataxia telangiectasia mutated-dependent manner

Chk2 is a serine/threonine kinase that signals to cell cycle arrest, DNA repair, and apoptotic pathways following DNA damage. It is activated by phosphorylation in response to ionizing radiation, UV light, stalled replication forks, and other types of DNA damage. Hypoxia is a common feature of solid tumors and has been shown to affect the regulation of many genes, including several DNA repair factors. We show here that Chk2 is phosphorylated on Thr68 and thereby activated in cells in response to hypoxia, and that this phosphorylation is dependent on the damage response kinase ataxia telangiectasia mutated (ATM) but not on the related kinase ATM and Rad3-related. Moreover, phosphorylation of Chk2 under hypoxia was attenuated in cells deficient in the repair factors MLH1 or NBS1. Finally, Chk2 serves to protect cells from apoptosis under hypoxic growth conditions. These results identify hypoxia as a new stimulus for Chk2 activation in an ATM-, MLH1-, and NBS1-dependent manner, and they suggest a novel pathway by which tumor hypoxia may influence cell survival and DNA repair.     

Enhanced gefitinib‐induced repression of the epidermal growth factor receptor pathway by ataxia telangiectasia‐mutated kinase inhibition in non‐small‐cell lung cancer cells

The epidermal growth factor receptor (EGFR) tyrosine kinase signaling pathways regulate cellular activities. The EGFR tyrosine kinase inhibitors (EGFR‐TKIs) repress the EGFR pathway constitutively activated by somatic EGFR gene mutations and have drastically improved the prognosis of non‐small‐cell lung cancer (NSCLC) patients. However, some problems, including resistance, remain to be solved. Recently, combination therapy with EGFR‐TKIs and cytotoxic agents has been shown to improve the prognosis of NSCLC patients. To enhance the anticancer effects of EGFR‐TKIs, we examined the cross‐talk of the EGFR pathways with ataxia telangiectasia‐mutated (ATM) signaling pathways. ATM is a key protein kinase in the DNA damage response and is known to phosphorylate Akt, an EGFR downstream factor. We found that the combination of an ATM inhibitor, KU55933, and an EGFR‐TKI, gefitinib, resulted in synergistic cell growth inhibition and induction of apoptosis in NSCLC cell lines carrying the sensitive EGFR mutation. We also found that KU55933 enhanced the gefitinib‐dependent repression of the phosphorylation of EGFR and/or its downstream factors. ATM inhibition may facilitate the gefitinib‐dependent repression of the phosphorylation of EGFR and/or its downstream factors, to exert anticancer effects against NSCLC cells with the sensitive EGFR mutation.     

53BP1 and NFBD1/MDC1-Nbs1 function in parallel interacting pathways activating ataxia-telangiectasia mutated (ATM) in response to DNA damage

53BP1 and NFBD1/MDC1 are recruited rapidly to sites of DNA double-strand breaks (DSBs), where they are hypothesized to function downstream of the ataxia-telangiectasia mutated (ATM) checkpoint kinase as "mediators" of DNA DSB signaling. To test this hypothesis, we suppressed 53BP1 and NFBD1/MDC1 expression by small interference RNA and monitored ATM autophosphorylation at Ser(1981) as a marker for ATM activation. Suppression of NFBD1/MDC1 led to decreased ATM activation and phosphorylation of ATM substrates. This phenotype was identical to that observed in cells with defective Nbs1 function and is consistent with recent observations identifying NFBD1/MDC1 as a component of the Mre11-Rad50-Nbs1 protein complex. In cells with wild-type Nbs1, suppression of 53BP1 expression had no effect on ATM activation but was associated with increased recruitment of NFBD1/MDC1 and Nbs1 to sites of DNA breaks, suggesting that decreased 53BP1 function might be compensated for by increased NFBD1/MDC1 and Nbs1 activity. Indeed, in cells with mutant Nbs1, suppression of 53BP1 led to decreased ATM activation and phosphorylation of ATM substrates. We conclude that DNA DSBs activate ATM through at least two independent pathways involving 53BP1 and NFBD1/MDC1-Nbs1, respectively.     

Activation of the Fanconi anemia/BRCA pathway and recombination repair in the cellular response to solar ultraviolet light

Recombination repair plays an important role in the processing of DNA double-strand breaks (DSB) and DNA cross-links, and has been suggested to be mediated by the activation of the Fanconi anemia (FA)/BRCA pathway. Unlike DNA damage generated by ionizing radiation or DNA cross-linking, UV light-induced DNA damage is not commonly thought to require recombination for processing, as UV light does not directly induce DSBs or DNA cross-links. To elucidate the role of recombination repair in the cellular response to UV, we studied the FA/BRCA pathway in primary skin cells exposed to solar-simulated light. UV-induced monoubiquitination of the FANCD2 protein and formation of FANCD2 nuclear foci confirmed the activation of the pathway by UV light. This was only observed when cells were irradiated during S phase and was not caused by directly UV-induced DSBs. UV-exposed cells did not exhibit FANCD2 nuclear foci once they entered mitosis or when growth-arrested. In addition, UV-induced nuclear foci of the recombination proteins, RAD51 and BRCA1, colocalized with FANCD2 foci. We suggest that in response to UV light, when nucleotide excision repair failed to repair, or when translesional DNA synthesis failed to bypass UV-induced DNA photoproducts, the FA/BRCA pathway mediates the recombination repair of replication forks stalled at DNA photoproducts as a third line of defense.     

Activation of ATM and Chk2 kinases in relation to the amount of DNA strand breaks

The diverse checkpoint responses to DNA damage may reflect differential sensitivities by molecular components of the damage-signalling network to the type and amount of lesions. Here, we determined the kinetics of activation of the checkpoint kinases ATM and Chk2 (the latter substrate of ATM) in relation to the initial yield of genomic DNA single-strand (SSBs) and double-strand breaks (DSBs). We show that doses of gamma-radiation (IR) as low as 0.25 Gy, which generate vast numbers of SSBs but only a few DSBs per cell (<8), promptly activate ATM kinase and induce the phosphorylation of the ATM substrates p53-Ser15, Nbs1-Ser343 and Chk2-Thr68. The full activation of Chk2 kinase, however, is triggered by treatments inflicting >19 DSBs per cell (e.g. 1 Gy), which cause Chk2 autophosphorylation on Thr387, Chk2-dependent accumulation of p21waf1 and checkpoint arrest in the S phase. Our results indicate that, in contrast to ATM, Chk2 activity is triggered by a greater number of DSBs, implying that, below a certain threshold level of lesions (<19 DSBs), DNA repair can occur through ATM, without enforcing Chk2-dependent checkpoints.     

Inhibition of novel GCN5–ATM axis restricts the onset of acquired drug resistance in leukemia

Leukemia is majorly treated by topoisomerase inhibitors that induce DNA double strand breaks (DSB) resulting in cell death. Consequently, modulation of DSB repair pathway renders leukemic cells resistant to therapy. As we do not fully understand the regulation of DSB repair acquired by resistant cells, targeting these cells has been a challenge. Here we investigated the regulation of DSB repair pathway in early drug resistant population (EDRP) and late drug resistant population (LDRP). We found that doxorubicin induced equal DSBs in parent and EDRP cells; however, cell death is induced only in the parent cells. Further analysis revealed that EDRP cells acquire relaxed chromatin via upregulation of lysine acetyl transferase KAT2A (GCN5). Drug treatment induces GCN5 interaction with ATM facilitating its recruitment to DSB sites. Hyperactivated ATM maximize H2AX, NBS1, BRCA1, Chk2, and Mcl‐1 activation, accelerating DNA repair and survival of EDRP cells. Consequently, inhibition of GCN5 significantly reduces ATM activation and survival of EDRP cells. Contrary to EDRP, doxorubicin failed to induce DSBs in LDRP because of reduced drug uptake and downregulation of TOP2β. Accordingly, ATM inhibition prior to doxorubicin treatment completely eliminated EDRP but not LDRP. Furthermore, baseline AML samples (n = 44) showed significantly higher GCN5 at mRNA and protein levels in MRD positive compared to MRD negative samples. Additionally, meta‐analysis (n = 221) showed high GCN5 expression correlates with poor overall survival. Together, these results provide important insights into the molecular mechanism specific to EDRP and will have implications for the development of novel therapeutics for AML.     

Interplay between ATM and ATR in the regulation of common fragile site stability

Common fragile sites are specific genomic loci that form constrictions and gaps on metaphase chromosomes under conditions that slow, but do not arrest, DNA replication. These sites have been shown to have a role in various chromosomal rearrangements in tumors. Different DNA damage response proteins were shown to regulate fragile site stability, including ataxia-telangiectasia and Rad3-related (ATR) and its effector Chk1. Here, we investigated the role of ataxia-telangiectasia mutated (ATM), the main transducer of DNA double-strand break (DSB) signal, in this regulation. We demonstrate that replication stress conditions, which induce fragile site expression, lead to DNA fragmentation and recruitment of phosphorylated ATM to nuclear foci at DSBs. We further show that ATM plays a role in maintaining fragile site stability, which is revealed only in the absence of ATR. However, the activation of ATM under these replication stress conditions is ATR independent. Following conditions that induce fragile site expression both ATR and ATM phosphorylate Chk1, suggesting that both proteins regulate fragile site expression probably via their effect on Chk1 activation. Our findings provide new insights into the interplay between ATR and ATM pathways in response to partial replication inhibition and in the regulation of fragile site stability.     

ATM-dependent activation of the gene encoding MAP kinase phosphatase 5 by radiomimetic DNA damage

Cellular responses to DNA damage are mediated by an extensive network of signaling pathways. The ATM protein kinase is a master regulator of the response to double-strand breaks (DSBs), the most cytotoxic DNA lesion caused by ionizing radiation. ATM is the protein missing or inactive in patients with the pleiotropic genetic disorder ataxia-telangiectasia (A-T). A major response to DNA damage is altered expression of numerous genes. While studying gene expression in control and A-T cells following treatment with the radiomimetic chemical neocarzinostatin (NCS), we identified an expressed sequence tag that represented a gene that was induced by DSBs in an ATM-dependent manner. The corresponding cDNA encoded a dual specificity phosphatase of the MAP kinase phosphatase family, MKP-5. MKP-5 dephosphorylates and inactivates the stress-activated MAP kinases JNK and p38. The phosphorylation-dephosphorylation cycle of JNK and p38 by NCS was attenuated in A-T cells. Thus, ATM modulates this cycle in response to DSBs. These results further highlight ATM as a link between the DNA damage response and major signaling pathways involved in proliferative and apoptotic processes.     

Endoplasmic reticulum stress pathway PERK‐eIF2α confers radioresistance in oropharyngeal carcinoma by activating NF‐κB

Endoplasmic reticulum stress (ERS) plays an important role in the pathogenesis and development of malignant tumors, as well as in the regulation of radiochemoresistance and chemoresistance in many malignancies. ERS signaling pathway protein kinase RNA‐like endoplasmic reticulum kinase (PERK)‐eukaryotic initiation factor‐2 (eIF2α) may induce aberrant activation of nuclear factor‐κB (NF‐κB). Our previous study showed that NF‐κB conferred radioresistance in lymphoma cells. However, whether PERK‐eIF2α regulates radioresistance in oropharyngeal carcinoma through NF‐κB activation is unknown. Herein, we showed that PERK overexpression correlated with a poor prognosis for patients with oropharyngeal carcinoma (P < 0.01). Meanwhile, the percentage of the high expression level of PERK in oropharyngeal carcinoma patients resistant to radiation was higher than in patients sensitive to radiation (77.7 and 33.3%, respectively; P < 0.05). Silencing PERK and eIF2α increased the radiosensitivity in oropharyngeal carcinoma cells and increased radiation‐induced apoptosis and G2/M phase arrest. PERK‐eIF2α silencing also inhibited radiation‐induced NF‐κB phosphorylation and increased the DNA double strand break‐related proteins ATM phosphorylation. NF‐κB activator TNF‐α and the ATM inhibitor Ku55933 offset the regulatory effect of eIF2α on the expression of radiation‐induced cell apoptosis‐related proteins and the G2/M phase arrest‐related proteins. These data indicate that PERK regulates radioresistance in oropharyngeal carcinoma through NF‐kB activation‐mediated phosphorylation of eIF2α, enhancing X‐ray‐induced activation of DNA DSB repair, cell apoptosis inhibition and G2/M cell cycle arrest.     

Genomic DNA is captured and amplified during double-strand break (DSB) repair in human cells

Genomic stability is maintained by the surveillance and repair of DNA damage. Here, we describe a mechanism whereby repair of extrachromosomal DNA double-strand breaks (DSBs) in human cells can be accompanied by capture of genomic DNA fragments. The availability of the human genome sequence enabled us to characterize these inserts in cells from a normal individual and from a patient with ataxia telangiectasia (AT), deficient for the damage response kinase ATM and prone to genomic instability. We find AT cells exhibit insertions of human chromosomal DNA fragments in excess of 17 kb during DSB repair, whereas we detected no such genomic inserts in normal cells. However, the presence of simian virus 40 (SV40), used to transform these cell lines, resulted in capture of genomic DNA associated with sites of viral integration in both cell types. The genomic instability at sites of SV40 integration was exported to other sites of DNA damage, and acquisition of the viral origin of replication resulted in gene amplification through autonomous replication of the plasmid harbouring the repaired extrachromosomal DSB. Should this same phenomenon apply to the repair of chromosomal DSBs, genome rearrangements made possible via this DSB insertional repair pose risks to genomic integrity, and may contribute to tumorigenic progression.     

Human nuclease/helicase DNA2 alleviates replication stress by promoting DNA end resection

In precancerous and cancerous lesions, excessive growth signals resulting from activation of oncogenes or loss of tumor suppressor genes lead to intensive replication stress, which is recognized by a high level of replication-associated DNA double-strand breaks (DSB). However, the molecular mechanism by which cells alleviate excessive replication stress remains unclear. In this study, we report that the human nuclease/helicase DNA2 facilitates homologous recombination to repair replication-associated DNA DSBs, thereby providing cells with survival advantages under conditions of replication stress. The nuclease activity of DNA2 was required for DSB end resection, which allowed subsequent recruitment of RPA and RAD51 to repair DSBs and restart replication. More importantly, DNA2 expression was significantly increased in human cancers and its expression correlated with patient outcome. Our findings therefore indicate that enhanced activity of DSB resection likely constitutes one mechanism whereby precancerous and cancerous cells might alleviate replication stress.