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Multiple autophosphorylation sites are dispensable for murine ATM activation in vivo
Correspondence to André Nussenzweig: andre_nussenzweig{at}nih.gov
Cellular responses to both physiological and pathological DNA double-strand breaks are initiated through activation of the evolutionarily conserved ataxia telangiectasia mutated (ATM) kinase. Upon DNA damage, an activation mechanism involving autophosphorylation has been reported to allow ATM to phosphorylate downstream targets important for cell cycle checkpoints and DNA repair. In humans, serine residues 367, 1893, and 1981 have been shown to be autophosphorylation sites that are individually required for ATM activation. To test the physiological importance of these sites, we generated a transgenic mouse model in which all three conserved ATM serine autophosphorylation sites (S367/1899/1987) have been replaced with alanine. In this study, we show that ATM-dependent responses at both cellular and organismal levels are functional in mice that express a triple serine mutant form of ATM as their sole ATM species. These results lend further support to the notion that ATM autophosphorylation correlates with the DNA damage–induced activation of the kinase but is not required for ATM function in vivo.
Abbreviations used in this paper: ATM, ataxia telangiectasia mutated; BAC, bacterial artificial chromosome; CSR, class switch recombination; DSB, double-strand break; LN, lymph node; LPS, lipopolysaccharide; MRN, MRE11–RAD50–NBS1; PE, phycoerythrin; SP, single positive; TCR, T cell receptor; Tg, transgene; WT, wild type.
This article is distributed under the terms of an Attribution–Noncommercial–Share Alike–No Mirror Sites license for the first six months after the publication date (see http://www.jcb.org/misc/terms.shtml). After six months it is available under a Creative Commons License (Attribution–Noncommercial–Share Alike 3.0 Unported license, as described at http://creativecommons.org/licenses/by-nc-sa/3.0/).
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irradiation as well as during normal physiological processes, including antigen receptor gene rearrangement and meiosis. Unrepaired DSBs are a source of genomic instability that can lead to uncontrolled cell proliferation and cancer (McKinnon and Caldecott, 2007). After sensor proteins recognize damaged chromatin, the ataxia telangiectasia mutated (ATM) kinase is recruited to the break site and initiates a cellular response through phosphorylation of consensus sites on numerous substrates that signal for repair of the DNA and/or prevent cell cycle progression (Shiloh, 2003). In addition to amplifying the DNA damage signal, ATM may also participate more directly in DNA repair by stabilizing repair complexes on damaged chromatin (Bredemeyer et al., 2006). The critical function of ATM in maintaining genomic stability is underscored by its high conservation in eukaryotes and its deficiency in the cancer-prone ataxia telangiectasia disease (Shiloh, 2003). ATM kinase activity is directly stimulated by damaged DNA and the MRE11–RAD50–NBS1 (MRN) sensor complex, which also stabilizes ATM to the break site (Girard et al., 2002; Carson et al., 2003; Uziel et al., 2003; Lee and Paull, 2004, 2005; Difilippantonio et al., 2005; Cerosaletti et al., 2006; Dupre et al., 2006; Berkovich et al., 2007; You et al., 2007). The DNA damage–induced activation of ATM results in the dissociation of inactive ATM dimers and/or multimers into enzymatically active monomers (Bakkenist and Kastan, 2003; Lee and Paull, 2004; Dupre et al., 2006). An autophosphorylation mechanism has been proposed to initiate ATM activation upon DNA damage by promoting monomerization and subsequent localization of ATM to break sites (Bakkenist and Kastan, 2003; Berkovich et al., 2007). In human cells, serine residues 367, 1893, and 1981 (S367, S1893, and S1981) have been shown to be autophosphorylation sites that are individually required for ATM activation and function (Bakkenist and Kastan, 2003; Kozlov et al., 2006). In a reconstituted in vitro system, however, evidence suggests that ATM monomerization by MRN does not require ATM S1981 autophosphorylation (Lee and Paull, 2005). Moreover, using Xenopus laevis egg extracts, high concentrations of damaged DNA can promote ATM monomerization without concomitant autophosphorylation (Dupre et al., 2006). Also, in a Xenopus system, there is evidence that ATM recruitment to DSBs can precede autophosphorylation (You et al., 2005), further questioning its importance in ATM activation. Because of the lack of physiologically relevant models, the significance of these autophosphorylation sites still remains poorly understood.
Using an ATM transgenic mouse model, we recently found that the most prominent S1981 autophosphorylation site in humans (S1987 in mice) is dispensable for murine ATM function in vivo (Pellegrini et al., 2006). To test whether other putative autophosphorylation sites compensate for the loss of murine S1987, we used bacterial artificial chromosome (BAC) recombineering to generate a transgenic mouse model in which all three conserved ATM serine autophosphorylation sites (S367/1899/1987) have been replaced with alanine. In this study, we show that ATM-dependent responses remain functionally intact in mice that express a double or triple serine mutant form of ATM as their sole ATM species. Collectively, our data strongly support the notion that DNA damage–induced activation of the ATM kinase does not depend on autophosphorylation.
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irradiation similarly to Atm+/+ and Atm+/– by displaying irradiation-induced phosphorylation of SMC1, KAP1, p53, and CHK2 (Fig. 1 C), which are events largely dependent on the ATM kinase (Banin et al., 1998; Canman et al., 1998; Matsuoka et al., 1998; Chaturvedi et al., 1999; Kim et al., 2002; Yazdi et al., 2002; Ziv et al., 2006). Another 3SA mutant founder (line Q2), which overexpressed ATM, also displayed similar irradiation-induced substrate phosphorylation (Fig. 1 C). Similar results were found in thymocytes (unpublished data). Moreover, no differences were found in AtmTg3SAAtm+/– transgenic mutants with one wild-type (WT) allele of Atm (Fig. 1 C and not depicted), arguing against a predicted dominant interfering activity (Bakkenist and Kastan, 2003; Pellegrini et al., 2006). Together, these results demonstrate that disruption of all three autophosphorylation sites does not affect DNA damage–induced ATM kinase activity in vivo. To complement our findings in primary mouse cells, we also tested whether all three autophosphorylation sites are required for ATM kinase activity in a completely reconstituted system. WT and 3SA mutant dimeric human ATM complexes were purified by sequential anti-Flag and anti-HA immunoprecipitation, and kinase assays were performed using p53 as a substrate (Lee and Paull, 2005). Consistent with previous findings that mutation of S1981 does not affect monomerization of ATM dimers or kinase activity (Lee and Paull, 2005), 3SA mutant ATM dimers also displayed kinase activity for p53 S15 in an MRN- and DNA-dependent manner similar to WT ATM dimers (Fig. 1 D). Collectively, our data suggest that autophosphorylation events at the conserved S1987, 367, and 1899 sites are dispensable for the kinase activity of ATM in response to DNA breaks.
Triple S1987/367/1899A mutant Atm mice display irradiation-induced chromatin retention, cell cycle checkpoint activation, and genomic stability
Evidence for the requirement of S1981 autophosphorylation in the accumulation of ATM at DSB sites is controversial (You et al., 2005; Pellegrini et al., 2006; Berkovich et al., 2007). In this study, using a biochemical method to detect chromatin retention of ATM protein after DNA damage (Andegeko et al., 2001), we found that mutant ATM from AtmTg3SAAtm–/– B cells accumulates onto chromatin after 10-Gy irradiation similarly to that from Atm+/+ (Fig. 2 A).
These results demonstrate that autophosphorylation at these three sites is dispensable for ATM retention on damaged chromatin.
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Lymphocytes from ATM-deficient patients and mice display general genomic instability as well as instability at the antigen receptor gene loci caused by aberrant V(D)J recombination (Xu, 1999; Callen et al., 2007b), a gene rearrangement process occurring in developing lymphocytes that increases the antibody repertoire of an individual for defense against pathogens. Characteristic translocations in mature T cells involving the T cell receptor (TCR) locus may contribute to the neoplastic transformation in lymphoid organs of ATM-deficient individuals (Matei et al., 2006; Callen et al., 2007a). To test the role of ATM autophosphorylation in preventing genomic instability, metaphases from Atm+/–, AtmTg3SAAtm–/–, and Atm–/– lymph node (LN) T cells were analyzed for chromosome abnormalities. Compared with Atm–/–, in which 32% of the metaphases displayed spontaneous chromosomal aberrations along with an additional 15% associated with the TCR locus, T cells from AtmTg3SAAtm–/– mice displayed aberrant metaphases similar to Atm+/– (Fig. 2 C). These data strongly suggest that autophosphorylation at S1987, S367, and S1899 are dispensable for the function of ATM in maintaining genomic stability.
Triple S1987/367/1899A mutant Atm mice display normal physiological responses during recombination and exposure to ionizing radiation
In the developing thymus, ATM functions in TCR-
gene rearrangement by facilitating the resolution of recombination activation gene–induced DSBs to promote TCR-β surface expression for subsequent CD4 and CD8 single-positive (SP) thymocyte selection (Matei et al., 2006; Huang et al., 2007; Vacchio et al., 2007). To begin examining the physiological role of multiple ATM autophosphorylation sites, we performed flow cytometry on freshly isolated thymocytes from Atm+/+, Atm+/–, AtmTg2SAAtm–/–, AtmTg3SAAtm–/–, and Atm–/– mice to assess thymocyte development. Percentages of CD4 and CD8 SP thymocytes in AtmTg2SAAtm–/– and AtmTg3SAAtm–/– mice were comparable with those found in Atm+/– mice, whereas thymocytes from Atm–/– mice showed characteristic reductions in both SP compartments (Fig. 3 A).
Moreover, thymocytes from both AtmTg2SAAtm–/– and AtmTg3SAAtm–/– mice displayed normal distributions of TCR-β surface expression, whereas Atm–/– thymocytes showed only low levels (Fig. 3 B), indicating that mice mutant for ATM autophosphorylation sites S1987, S367, and S1899 maintain competency for TCR- rearrangement and thymocyte development.
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-1 constant region locus. Although Atm–/– mice displayed a reduction in IgG1-positive cells (Lumsden et al., 2004; Reina-San-Martin et al., 2004), B cells from both AtmTg2SAAtm–/– and AtmTg3SAAtm–/– mice exhibited levels of IgG1 switching similar to Atm+/– (Fig. 3 C). These results suggest that ATM activation and function during CSR is intact in the absence of S1987, S367, and S1899 autophosphorylation. The infertility of both male and female Atm–/– mice results from a lack of mature gametes caused by chromosomal fragmentation and arrest during meiosis (Barlow et al., 1996; Elson et al., 1996; Xu et al., 1996). AtmTg3SAAtm–/– mice had normal testes size and numbers of spermatids within the seminiferous tubules compared with the degeneration and complete absence of spermatids in Atm–/– testes (Fig. 3 D). Similar results were obtained from ovaries of AtmTg3SAAtm–/– mice (unpublished data). Thus, spermatogenesis and oogenesis disrupted in Atm–/– mice appear to be normal in AtmTg3SAAtm–/– mice. Collectively, our results demonstrate that physiological DNA rearrangements that require ATM function to resolve DSBs during V(D)J, CSR, and meiotic recombination are not dependent on ATM autophosphorylation at S1987, S367, and S1899.
A hallmark of ataxia telangiectasia is extreme sensitivity to the effects of ionizing radiation (Taylor and Byrd, 2005). Upon radiation exposure, the death of Atm–/– mice results from acute radiation toxicity to the gastrointestinal tract (Barlow et al., 1996). To further investigate whether multiple ATM autophosphorylation sites are important for ATM function in vivo, mice were subjected to 8 Gy of whole-body irradiation. Intestinal tissues were histologically examined 4 d after irradiation. Recovery from irradiation in the small intestines was similar in Atm+/–, AtmTg3SAAtm–/–, and AtmTg3SAAtm+/– mice, whereas Atm–/– mice displayed characteristic toxicity indicated by severe epithelial crypt degeneration and loss of villi (Fig. 4).
Examination of the large intestines yielded similar results (unpublished data). These data indicate that ATM autophosphorylation at S1987, S367, and S1899 are not essential for ATM function in vivo to promote tissue recovery after exposure to ionizing radiation.
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Our results from transgenic mouse models strongly suggest that ATM autophosphorylation at S1987, S367, and S1899 is dispensable for the DNA damage–induced activation and function of the kinase in vivo. We show that 3SA autophosphorylation mutant ATM can accumulate at sites of DNA damage, phosphorylate target substrates, activate cell cycle checkpoints, maintain genomic stability, and function in lymphocyte and meiotic recombination processes as well as in the recovery from whole-body irradiation. Because expression of the mutant ATM protein is 2.5-fold higher than normal, it is possible that this could mask a nonessential role for ATM autophosphorylation on ATM activity. For example, if ATM autophosphorylation were to enhance ATM activity 2.5-fold and the nonphosphorylatable ATM were expressed 2.5-fold higher than normal, mice expressing the Tg might be normal in terms of ATM function. This seems unlikely because levels of ATM expressed over a range of one- to sixfold higher than normal in AtmTgWT and AtmTgS1987A mice (Pellegrini et al., 2006) display indistinguishable ATM substrate phosphorylations compared with Atm+/– and Atm+/+ controls. Moreover, TgWT, TgS1987A, Tg2SA, and Tg3SA completely rescue the defects in growth, lymphocyte development, and meiotic arrest observed in Atm–/– mice (Pellegrini et al., 2006). On a different note, at least three other ATM phosphorylation sites have been identified in response to DNA damage besides S367, S1893, and S1981 (Kozlov et al., 2006; Matsuoka et al., 2007), some of which may also be sites of autophosphorylation, raising the formal possibility that other autophosphorylation sites may still compensate for the loss of S1987/367/1899. Nevertheless, pretreatment of human cells in culture with the KU55933 ATM kinase inhibitor did not affect the irradiation-induced increase in ATM kinase activity (Pellegrini et al., 2006), providing additional evidence against an essential role for autophosphorylation in ATM activation.
Collectively with our in vivo evidence, we propose that ATM autophosphorylation occurs simultaneously or as a consequence of ATM activation and may be the combined result of ATM localization to break sites along with promiscuous phosphorylation of consensus sites exposed on the surface of ATM. By proposing that autophosphorylation is not the mechanism of ATM activation, we stimulate speculation on the relevant way in which damaged chromatin activates the ATM kinase. The MRN complex clearly plays a critical role in ATM activation by retaining ATM to DNA breaks, stimulating substrate binding, and directly stimulating kinase activity through activities on DNA by the RAD50 ATPase (Lee and Paull, 2007). Growing evidence suggests that ATM activation at DNA damage sites is mediated through direct recruitment by MRN, and to what extent other posttranslational modifications of ATM, such as acetylation at lysine 3016 (Sun et al., 2007), may function remains to be determined.
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Materials and methods |
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Lymphocyte cultures
B cells were isolated from spleens of 6–12-wk-old mice by immunomagnetic depletion with anti-CD43 beads (Miltenyi Biotech) and stimulated with either 25 µg/ml lipopolysaccharide (LPS) alone (Sigma-Aldrich) or in combination with 5 ng/ml interleukin 4 (IL4; Sigma-Aldrich) for 2–4 d as indicated. LN T cells of 6–12-wk-old mice were stimulated with 2 µg/ml anti–TCR-β (H57; BD) and 5 µg/ml anti-CD28 (BD) antibodies for 48 h.
Western blotting
Whole cell lysates were prepared as previously described (Difilippantonio et al., 2005). The association of ATM with chromatin after irradiation was determined using detergent extraction as previously described (Andegeko et al., 2001). Anti-KAP1 S824 phospho (Bethyl Laboratories, Inc.) was used at a 1:2,000 dilution. All other antibodies used for Western blotting were previously described (Lee and Paull, 2005; Pellegrini et al., 2006). Human ATM dimers and/or multimers were purified by sequential anti-Flag and anti-HA immunoprecipitation, and kinase assays were performed as previously described (Lee and Paull, 2005).
Metaphase and G2/M checkpoint analysis
Cultured LN T cells were arrested at mitosis with 0.1 µg/ml colcemid (Roche) treatment for 1 h, and metaphase chromosome spreads were prepared according to standard procedures. FISH was performed on slides with probes for TCR-C– (from BAC 232F18), chromosome 14 (a gift from T. Reid, National Cancer Institute, Bethesda, MD), and telomere repeat–specific peptide nucleic acid (Applied Biosystems) and counterstained with DAPI. Images were acquired with an upright microscope (Axioplan2; Carl Zeiss, Inc.) equipped with a 63x NA 1.4 objective lens (Plan-Apochromat; Nikon) and a monochrome charge-coupled device camera (Orca ER; Hamamatsu Photonics) using Metamorph software (MDS Analytical Technologies). G2/M checkpoint assays were performed on stimulated B cells as previously described (Fernandez-Capetillo et al., 2002).
Flow cytometry
Single-cell suspensions of thymocytes were stained with anti–CD4-phycoerythrin (PE), anti–CD8-FITC, or anti–TCR-β–PE (BD). B cells cultured for 4 d were harvested and stained in single-cell suspensions with anti–B220-FITC and anti–IgG1-biotin followed by streptavidin-PE. Cells were acquired with either a FACScan or a FACSCalibur (BD) along with CellQuest software (BD) using a live lymphocyte gate except for a propidium iodide–negative gate used in CSR analysis of B cells. Data were analyzed using FlowJo software (version 7.2.4; Tree Star, Inc.).
Histology
Testes and small intestines were fixed in 10% formalin, and paraffin sections were stained with hematoxylin and eosin. Images were acquired with an inverted microscope (Axiovert 200M; Carl Zeiss, Inc.) equipped with a 10x NA 0.45 objective lens (Plan-Apochromat; Nikon) and a color charge-coupled device camera (Axiocam MRc5; Carl Zeiss, Inc.) using AxioVision software (version 4.6.3.0; Carl Zeiss, Inc.).
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Acknowledgments |
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This work was supported by the Intramural Research Program of the National Institutes of Health, National Cancer Institute, Center for Cancer Research, and the A-T Children's Project.
Submitted: 26 May 2008
Accepted: 30 October 2008
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2.5-fold higher than endogenous levels in Atm+/+ mice. Line Q2 denotes a different 3SA mutant founder line that expresses mutant ATM 
