Published online Jan 15, 2004. doi: 10.3748/wjg.v10.i2.155
Revised: August 10, 2003
Accepted: August 18, 2003
Published online: January 15, 2004
Cellular response to genotoxic stress is a very complex process, and it usually starts with the “sensing” or “detection” of the DNA damage, followed by a series of events that include signal transduction and activation of transcription factors. The activated transcription factors induce expressions of many genes which are involved in cellular functions such as DNA repair, cell cycle arrest, and cell death. There have been extensive studies from multiple disciplines exploring the mechanisms of cellular genotoxic responses, which have resulted in the identification of many cellular components involved in this process, including the mitogen-activated protein kinases (MAPKs) cascade. Although the initial activation of protein kinase cascade is not fully understood, human protein kinases ATM (ataxia-telangiectasia, mutated) and ATR (ATM and Rad3-related) are emerging as potential sensors of DNA damage. Current progresses in ATM/ATR research and related signaling pathways are discussed in this review, in an effort to facilitate a better understanding of genotoxic stress response.
- Citation: Yang J, Xu ZP, Huang Y, Hamrick HE, Duerksen-Hughes PJ, Yu YN. ATM and ATR: Sensing DNA damage. World J Gastroenterol 2004; 10(2): 155-160
- URL: https://www.wjgnet.com/1007-9327/full/v10/i2/155.htm
- DOI: https://dx.doi.org/10.3748/wjg.v10.i2.155
Cellular response to genotoxic stress is a very complex process. However, it can be “simply” envisioned as a signal transduction cascade in which DNA lesions act as the initial signal that is detected by sensors and passed down through transducers. Eventually the effectors receive the signal and execute various cellular functions (Figure 1). Much knowledge has been gained over the years concerning the signal transducers, and a large group of serine-threonine protein kinases, namely the mitogen-activated protein kinases (MAPKs), along with their upstream kinases, have been shown to play prominent roles in cellular genotoxic responses[1]. Three major classes of MAPKs, i.e., extracellular signal-regulated kinase (ERK), c-Jun N-terminal kinase/stress-activated protein kinase (JNK/SAPK), and p38 (also known as SAPK2, RK, CSBP, or Mxi2), could all be activated by various genotoxic stresses[1-7]. Although the precise mechanism has not been fully understood, it is known that damage to cellular DNA somehow leads to the activation of a group of serine-threonine kinases called MAPK kinase kinases (MAPKKK, or MEKK, MEK kinase), which phosphorylate the downstream dual-specificity kinases called MAPK kinases (MAPKK, or MEK, MAPK/ERK kinase). These MAPKKs then phosphorylate the threonine and tyrosine residues in MAPKs. This three-component module could be assembled together by scaffold proteins that ensure the efficiency and specificity of each individual MAPK pathway[8-10]. The activated MAPKs then translocate to the nucleus and phosphorylate scores of target proteins, including many transcription factors. Among these transcription factors is the tumor suppressor p53 protein, which plays such an important role in the genotoxic stress response that has earned the reputation as the “universal sensor for genotoxic stress”[2,11,12].
Although studies on MAPKs have provided a lot useful information about signal transducers, the initial sensors for DNA damage remain to be identified. Recently, it has been proposed that some multi-protein complexes that are involved in DNA maintenance or repair, such as the Rad family member Rad1, 9, 17, 26, and Hus1, might function as DNA damage sensors[13-18]. Members of the phosphatidylinositol 3-kinase (PI-3) superfamily, which are activated at the very early stages of DNA damage response, could also serve as sensors, as well as initiators, of the ensuing cellular genotoxic stress response, including ATM and ATR in humans[19]. Although these proteins share the PI-3-like kinase domain, they could not function as lipid kinases, but rather as serine-threonine protein kinases[14,20-25].
One distinguishing characteristic of the PI-3 family members is their unusually large size, which ranges from around 300 kDa to over 500 kDa. ATM is a 3 056 amino acid (aa) protein while ATR is a 2 644 aa protein, and both have a C-terminal catalytic domain (-300 aa) which is flanked by two loosely conserved domains. Although it has not been known how exactly these two kinases sense the DNA damage, it is clear that both kinases can be activated by DNA damage. However, it has been found that ATM responds primarily to double-strand breaks induced by ionizing irradiation (IR), while ATR also reacts to UV or stalled replication forks[13,14,26-29].
Several mechanisms have been proposed for the activation of ATM and ATR by DNA damage: a) direct activation through interaction with damaged DNA, b) indirect activation through interaction with DNA repair or maintenance proteins, or c) a combination of both[30]. Existing experimental data support the third mechanism, that they are activated both through interactions with DNA and members of the repair complexes. For example, ATM could bind directly to DNA. Furthermore, pre-treatment of DNA-cellulose matrix with IR or restriction enzymes could stimulate ATM binding, suggesting that ATM binds to DNA ends[31,32]. ATR could also bind to DNA, with a higher affinity to UV-damaged than undamaged DNA. In addition, damaged DNA could stimulate the kinase activity of ATR to a significantly higher level than undamaged DNA[33,34]. ATM and ATR also interact with many proteins that co-localize at the site of DNA damage. For example, ATM as a part of a super protein complex called BRCA1-associated genome surveillance complex (BASC), is involved in the recognition and repair of aberrant DNA structures. It has been found this complex contains several other proteins such as breast cancer gene 1 (BRCA1), mismatch-repair protein hRad50, and BLM helicase[35]. ATM could bind to histone deacetylase HDAC1 both in vitro and in vivo, and the extent of this association was increased after exposure of MRC5CV1 human fibroblasts to IR[36]. ATR was also able to bind to Rad17[37] and BRCA1[38], and associated with components of the nucleosome remodeling and deacetylating (NRD) complex such as chromodomain-helicase-DNA-binding protein 4 (CHD4) and histone-deacetylase-2 (HDAC2)[39]. All these data support the model that multiple checkpoint protein complexes localize at the sites of DNA damage independently and interact to trigger the checkpoint-signaling cascade.
c-Abl, a non-receptor tyrosine kinase that is ubiquitously expressed and localized in both nucleus and cytoplasm, could be up-regulated following exposure to IR or genotoxic chemicals such as cisplatin, methyl methane sulfonate (MMS), mitomycin-C, hydrogen peroxide, but not UV[3,40-42]. IR-induced activation of c-Abl has been shown to require the involvement of ATM in some cases, with ATM phosphorylating serine residue 465 located within the kinase domain of c-Abl[43-45]. However, other studies found that c-Abl was not essential for ATM function in chromosomal maintenance, suggesting that c-Abl and ATM are at least partially independent[46].
An important effect which has been found following the activation of c-Abl, is the induction of cell cycle arrest in a p53-dependent manner, with the possible involvement of Rb, but not P21Cip[47,48]. c-Abl could directly interact with and phosphorylate p53, and regulate the level of p53 by preventing its nuclear export and ubiquitination-dependent degradation[49,50]. It could also induce apoptosis in response to DNA damage[51,52], although this activity involved collaboration with p73 more than p53[53-55]. c-Abl binds to p73 through its Src-homology (SH3) domain to phosphorylate p73 at tyrosine residues, which in turn activates p73-dependent apoptosis pathway.
Since p53 is such an important mediator in cellular response to genotoxic stress, it is no wonder that ATM/ATR can regulate p53 activity at multiple levels (Figure 2). The most straightforward way to manage p53 is through direct interaction,e.g. , phosphorylation of p53. Both ATM and ATR have been shown to phosphorylate p53 protein at serine 15 to enhance its transactivating activity[56-59]. ATM is also required for dephosphorylation of Ser 376, which can create a binding site for 14-3-3 protein. The association of p53 and 14-3-3 could increase the affinity of p53 for its specific DNA sequence, therefore enhancing its transcriptional activity[60]. Other sites that could be phosphorylated by ATM on p53 include Ser 6, 9, 46, and Thr 18, which may be important for the apoptotic activity of p53 (Ser 46) or may enhance the acetylation of p53 (Ser 6, 9, Thr18)[61]. In addition, ATM/ATR could regulate p53 through the action of other kinases. For example, ATM-activated c-Abl could phosphorylate p53 at Ser 20, which is important for the stabilization of p53 since this modification interferes with the binding between p53 and its regulator murine double minute 2 (Mdm2)[49,62]. ATM-activated Chk2 could also phosphorylate p53 protein at Ser 20 and possibly at other sites, leading to the activation of p53[63-65]. Furthermore, ATM has been found able to bind and phosphorylate Mdm2 and HDM2 (the human homologue of Mdm2), thus inhibiting p53 degradation and promoting its accumulation in cells[66-68].
Accumulative data support the notion that the activation of MAPKs in response to genotoxic stress is ATM/ATR dependent. For example, DNA damaging stimuli, including etoposide (ETOP), adriamycin (ADR), IR, and UV could activate ERK1/2 in primary (MEF and IMR90), immortalized (NIH3T3) and transformed (MCF-7) cells. It has further been shown that ERK activation in response to ETOP could be abolished in ATM-/- fibroblasts (GM05823) independenty of p53[69]. UVA (320-400 nm) triggered ATM-dependent p53 phosphorylation and JNK activation that resulted in apoptosis, while ATR was required for UVC (200-290 nm)-mediated p53 phosphorylation and JNK activation[70]. In addition, activation of ATM by gamma irradiation could lead to the activation of MKK6 and p38γ isoform, and that activation of both MKK6 and p38γ was essential for the proper regulation of G2 checkpoint in mammalian cells[71].
Although the link between ATM/ATR and MAPKs has been established, it is still not clear how ATM/ATR activates MAPKs. In general, MAPK pathways are activated by extracellular signals or signals generated in the cytoplasm, and then the activated MAPKs transduce the specific “messages” to the nucleus. However, in response to genotoxic stress, the signal seems to flow from the nucleus to the cytoplasm to activate MAPKs. In this case, c-Abl kinase may provide an explanation. It has been found that c-Abl can activate p38 through MKK6[72-74], and JNK by translocating from nucleus to cytoplasm to phosphorylate hematopoietic progenitor kinase (HPK1), an upstream kinase of JNK[75]. Therefore, c-Abl may fulfill a role as the message carrier to transduce signals between subcellular locations. This may further explain why in response to genotoxic stress the activation of p38 was rather late (- 1 h) and prolonged[71], while the cytokine activation of p38 was rapid and transient (maximum around 30-60 min)[76].
In addition to their ability to activate MAPKs, ATM/ATR may also regulate these kinases through their negative regulators, the dual specificity of phosphatase MAPK and phosphatase family (MKP). One member of the MKP family, MKP-5, is known to dephosphorylate and inactivate the stress-activated JNK and p38. Thephosphorylation - dephosphorylation cycle of JNK and p38 stimulated by radiomimetic chemical neocarzinostatin (NCS), which can induce double strand breaks (DSBs), could be attenuated in A-T cells[77], further emphasizing the role of ATM as a master regulator in the cellular response to genotoxic stress.
Homozygous mutations in the ATM gene can cause human genetic disorder ataxia-telangiectasia (A-T), which is characterized by cerebellar degeneration, immunodeficiency, cancer predisposition, and acute sensitivity to IR. The affected individual has been found to be prone to develop T cell pro-lymphocytic leukemia, B cell chronic lymphocytic leukemia, as well as sporadic colon cancer with microsatellite instability[78]. Atm-deficient mice also showed a striking predisposition to lymphoid malignancies, particularly thymic lymphomas, to which they succumbed before the age of 1 year. However, much of the literature on ATM mutations and cancer was not about A-T patients, but was, instead, on heterozygous carriers of A-T mutations. For example, recent studies have found an unusually high occurrence of breast cancer in the relatives of A-T patients, and that loss of heterozygosity of ATM occurred frequently during the early stages of breast cancer development[79]. Furthermore, heterozygous mice were more sensitive to radiation-induced cataracts than their wild-type counterparts[80]. Spring et al[81] established a knock-in mouse mutant in which an inframe deletion was previously found to cause A-T in humans was induced. Mice homozygous for this mutation could produce small amounts of inactive ATM and usually showed the hallmarks of the Atm-knockout phenotype. Notably, mice heterozygous for this mutation were predisposed to various cancers, unlike the animals that carry a single knockout allele that does not produce any protein. Therefore, ATM heterozygotes in human population might also be more radiosensitive, and have a higher risk for cancer[82](Figure 3).
No human disease has been found to link to defects in ATR, although it was found that defects in ATR led to embryonic lethality in mice, suggesting that ATR is essential for of development of ATR[83,84]. Nonetheless, it is known that over-expressing the inactive form of ATR had a dominant negative effect, causing increased sensitivity to DNA damaging stimuli and failure to activate cell cycle checkpoints in response to IR[28,85]. Finally, over-expressing active ATR could restore S phase checkpoint defect in A-T cells, suggesting that ATM and ATR may complement each other in the cellular genotoxic stress response[85].
Once the sensors detect DNA damage and initiate the signaling pathway, and the biological consequences (including DNA repair, cell cycle arrest, and apoptosis) take effect, the signals need to be inactivated or attenuated. The regulation of some downstream components in the cellular genotoxic stress response has been rather clearly defined, and usually involves a negative feedback mechanism. One such example is the p53-Mdm2 regulation loop. In this loop p53 could activate the expression of Mdm2, and Mdm2 could mediate the rapid degradation of p53 through the ubiquitin pathway[62]. MAPKs have a similar feedback regulation mechanism with MKPs. MAPKs could induce the expression of MKPs, and MKPs then could interact with specific MAPKs to deactivate them through dephosphorylation[1]. On the other hand, the mechanisms for the regulation of ATM and ATR, remain obscure, although some recent studies have significantly advanced our understanding.
In contrast to the vast volume of reports about the activation of ATM under genotoxic stress, very few studies have been conducted to evaluate how ATM was inactivated. The results from these studies so far all pointed toward inactivation of ATM through Caspase-mediated cleavage during apoptosis[86-88]. This same mechanism has also been shown to regulate many other proteins involved in apoptosis, including serine/threonine protein kinase Cδ (PKCδ), Mdm2, PARP, replication factor C, 70 kDa U1snRNP, fodrin and lamins[87]. It was reported that during apoptosis induced by c-Myc or DNA-damaging agents (such as etoposide or IR), ATM but not ATR, was specifically cleaved by members of the Caspase family. Detailed studies revealed that the Caspase responsible for this cleavage was either Caspase-3 or -7, but not Caspase-6. This cleavage abrogated the kinase activity of ATM to phosphorylate p53, although the resulting two fragments retained their DNA binding ability and interacted with each other. This finding led to the hypothesis that cleaved ATM protein, without its kinase activity, might act in a trans-dominant-negative fashion to compete with the intact ATM, thus preventing DNA repair and DNA damage signaling through its binding to DNA[86-88].
Even less information is available regarding the inactivation of ATR. However, the recent identification of an ATR-interacting protein (ATRIP) might provide a lead for future studies[89]. ATRIP is an 86-kDa protein with a coiled-coil domain near its N-terminal and its expression is regulated by ATR. The deletion of ATR mediated by Cre recombinase could cause the loss of both ATR and ATRIP expression, along with the loss of DNA damage checkpoint responses and cell death. ATRIP could be phosphorylated by ATR and co-localized at intranuclear foci with ATR after DNA damage caused by hydroxyurea (HU), IR, or UV, or inhibition of DNA replication. Conversely, ATRIP could also regulate the expression of ATR, as inhibition of ATRIP expression with small interference RNA (siRNA) would result in decreased ATR protein expression, while ATR mRNA levels would not be affected. Interference with ATRIP function could cause the same loss of G2-M response to DNA damage as that seen in the case of ATR deletion, suggesting that these two proteins work as mutually dependent partners in cell cycle checkpoint pathways[89].
Human cancer is a major health issue for society, causing millions of deaths each year and huge economical losses. Since most of human carcinogens are genotoxins[90,91], considerable resources have been and are being expended in efforts to understand the mechansm of genotoxin - induced carcinogenesis, thus leading to a better prevention or even the treatment of cancer. Since the sensing of DNA damage is one of the earliest steps in the cellular response to gentoxic stress, identification of these “sensors” is the most prominent challenge. As discussed in this review, ATM and ATR are showing their promise as potential candidates. However, what we should keep in mind is that detection of DNA damage may not be such a simple process, and may require more than just one or two proteins to fulfill this role. Supporting this idea is the finding of “foci” at damaged DNA sites, where many proteins involved in DNA repair and maintenance aggregate. It is more likely that interactions of these proteins, combined with some unidentified factors might function as DNA damage sensors[92]. Further elucidation of these “foci” will be an exciting area for future research.
Edited by Zhu LH and Wang XL
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