Abstract
The Mre11 complex promotes DNA double-strand break repair and regulates DNA damage signaling via activation of the ataxia-telangiectasia mutated (ATM) kinase. The hypermorphic Rad50S allele encodes a variant of Rad50, a member of the Mre11 complex. Cells expressing Rad50S experience constitutive ATM activation, which leads to precipitous apoptotic attrition in hematopoietic cells. In this study, we show that ATM activation by the Rad50S-containing Mre11 complex enhances the proliferation of LSK cells, a population consisting of hematopoietic stem cells and multipotent progenitor cells. In Rad50S/S mice, enhanced LSK proliferation triggers apoptotic attrition. This phenotype is mitigated when Rad50S/S is combined with mutations that alter either LSK cell quiescence (myeloid elf-1–like factor/ELF4–deficient mice) or hematopoietic differentiation (p21- and p27-deficient mice), indicating that the LSK population is a primary target of Rad50S pathology. We show that cells from Rad50S/S mice are hypersensitive to camptothecin, a topoisomerase I inhibitor that causes DNA damage primarily during DNA replication. On this basis, we propose that apoptotic attrition of Rad50S/S hematopoietic cells results from enhanced proliferation in the context of topoisomerase-associated DNA damage. Impairment of apoptosis in Rad50S/S mice promotes hematopoietic malignancy, suggesting that primitive hematopoietic cells serve as a reservoir of potentially oncogenic lesions in Rad50S/S mice. These data provide compelling evidence that the Mre11 complex plays a role in the metabolism of topoisomerase lesions in mammals, and further suggest that such lesions can accumulate in primitive hematopoietic cells and confer significant oncogenic potential. [Cancer Res 2008;68(7):2186–93]
Introduction
The Mre11 complex, consisting of Mre11, Rad50, and Nbs1, plays a pivotal role in the DNA damage response, mediating both ataxia-telangiectasia mutated (ATM)–dependent DNA damage signaling and recombinational DNA repair (1). The human chromosome fragility syndromes Nijmegen breakage syndrome and the ataxia-telangiectasia–like disorder (ATLD) result from hypomorphic Nbs1 and Mre11 alleles, respectively (2, 3). Cells from mice modeling those disorders exhibit defects in ATM-dependent cell cycle checkpoint functions, as well as hypersensitivity to clastogenic agents such as ionizing radiation. Conversely, mice expressing the Rad50S mutation (Rad50K22M) are hypermorphic for ATM-dependent signaling and constitutively exhibit indices of genotoxic stress (4–6).
Although the cellular phenotypes of the Rad50S/S mutants are mild, the Rad50S mutation exerts a profound effect at the organismal level. By 4 weeks of age, the bone marrow of Rad50S/S mice is completely devoid of hematopoietic cells, and by 2 months of age most Rad50S/S mice die of anemia. Bone marrow reconstitution experiments suggest that this decrement in hematopoietic cellularity results from apoptotic attrition of primitive hematopoietic cells, including the hematopoietic stem cell (HSC) pool. The apoptotic attrition observed is dependent on the DNA damage response pathway governed by the Mre11 complex and ATM (5).
No sensitivity to ionizing radiation, UV radiation, hydroxyurea, or mitomycin C was observed in Rad50S/S cells, and ionizing radiation treatment of Rad50S/S cells did not result in increased chromosomal aberrations (4, 6). These findings are inconsistent with the interpretation that chronic ATM activation in Rad50S/S cells reflected a DNA repair defect. However, in addition to its role in recombinational DNA repair, the Mre11 complex has been implicated in the removal of topoisomerase lesions in several organisms, and the possibility that the metabolism of such lesions is impaired by the Rad50S mutation is addressed in this study.
Recent data support the existence of an endonucleolytic DNA repair pathway for the removal of topoisomerase II (Topo II) from DNA ends (7). The cellular nuclease(s) acting in the presumptive Topo II removal pathway are not known. However, the available evidence suggests that the Mre11 nuclease is a likely candidate. For example, Spo11 is liberated from meiotic double-strand break ends covalently bound to short oligonucleotides. The production of this species is blocked in Mre11 nuclease–dead mutants as well as rad50S strains. In addition, gp46/gp47 (the Mre11 complex in bacteriophage T4) is required for the nucleolytic removal of covalently attached Topo II in that organism (8–10), and the removal of the terminal protein of adenovirus seems to be blocked by Mre11 depletion in human cells (11). The S. cerevisiae Mre11 complex has also been implicated in the repair of topoisomerase I (Topo I) lesions. Rad50 and Mre11 deficiency confers sensitivity to the Topo I inhibitor camptothecin. Reminiscent of Spo11 removal, camptothecin sensitivity is also seen in Mre11 nuclease–dead and Rad50S/S mutants, suggesting a role for the Mre11 nuclease in the removal of covalently bound Topo I complexes (12–14).
In this study, we show that precipitous apoptotic loss of hematopoietic cells in Rad50S/S mice is due to an intrinsic effect on primitive hematopoietic cells [lineage-negative, Sca-1+, c-kit+ (LSK cells hereafter)]. The hematopoietic attrition is mitigated in genetic contexts that alter LSK cell quiescence or inhibit differentiation, which suggests that the HSC is the primary cell type affected. Activation of the DNA damage response by the Rad50S allele causes enhanced proliferation of the LSK pool, which correlates with the induction of apoptosis. When apoptosis is abrogated, LSK cells remain proliferative, suggesting that the Rad50S mutation and, by extension, the ATM-dependent DNA damage response reduce quiescence of primitive hematopoietic cells. Further, we present evidence that the repair of topoisomerase lesions is impaired in Rad50S/S cells, supporting the view that the Mre11 complex participates in the repair of these lesions in vivo. This repair pathway is significant for tumor suppression, as indicated by the fact that apoptotically compromised Rad50S/S mice present with myriad hematologic malignancies.
Materials and Methods
Mice derivation and genotyping. Rad50S/S, Mef−/−, p21−/−, p27−/−, Atm−/−, Mre11ATLD1/ATLD1, Chk2−/−, Rad50S/S Atm−/−, Rad50S/S Mre11ATLD1/ATLD1, and Rad50S/S Chk2−/− survival and genotyping have been described (3, 5, 6, 15–19). Rad50S/S Mef−/−, Rad50S/S p21−/−, and Rad50S/S p27−/− double mutant animals were generated in this study. All mice were derived at Memorial Sloan Kettering Cancer Center and maintained on mixed 129/SvEv and C57BL/6 background. All experiments involving animals conform to Institutional Animal Care and Use Committee institutional and national standards.
Survival analyses and statistical significance. Kaplan-Meier survival curves were made with Prism 4 (GraphPad Software). Statistical significance for all studies was determined by a two-sided Wilcoxon rank sum test using Mstat software (Norman Drinkwater, McArdle Laboratory for Cancer Research).
Hematopoietic cell preparation and analysis. Single-cell suspensions from the bone marrow were depleted of RBC by hypotonic lysis and maintained in PBS. Labeled antibodies specific for B220 (phycoerythrin), IgM (FITC), CD43 (FITC), Cd11b (phycoerythrin), Gr-1 (FITC), c-kit (allophycocyanin), Sca-1 (phycoerythrin), Annexin V (FITC), biotinylated mouse lineage panel, and streptavidin-allophycocyanin-Cy7 were from BD Biosciences PharMingen. Ki-67 (FITC) antibody was from Vector Lab, Inc., and Hoechst 33342 from Molecular Probes. Dead cells were excluded by propidium iodide staining. The number of pro-B cells was equal to the number of B220 CD43 double-positive bone marrow cells; the number of pre-B cells was the number of B220-positive, CD43-negative, IgM-negative cells; the number of Immature B cells was the number of B220 IgM double-positive cells; and the number of myeloid cells was the number of Gr-1 Cd11b double-positive cells. The number of LSK cells was the number of lineage-negative, c-kit–positive, Sca-1–positive cells, and the number of progenitors was the number of lineage-negative, Sca-1–negative, c-kit–positive cells. Fluorescence-activated cell sorting (FACS) analyses were done on FACSCalibur Instruments (Becton Dickinson).
Colony-forming cell assay. Clonogenic progenitors were determined in methylcellulose medium (MethoCult GF M3434, Stem Cell Technologies) using 2 × 104 bone marrow mononuclear cells per well (six-well plate). Colonies were scored after 10 d of incubation and expressed as number of colony-forming cells (CFC) per total bone marrow (two femurs and two tibias).
Cell derivation and culture. Murine embryonic fibroblasts (MEF) and murine ear fibroblasts were generated and cultured as described (6). SV40 immortalization was achieved as described (6).
Cellular assays. Sensitivity to clastogens was assessed by colony formation assays as described (3) and the surviving fraction was determined after 9 d in culture. Metaphase preparations, conventional karyotypic analyses, and telomere fluorescence in situ hybridization (FISH) analyses were done as previously described (6). For sister chromatid exchange (SCE) analyses, cells were grown for 40 h in 30 μg/mL bromodeoxyuridine, and camptothecin treatments were done as for the conventional analyses. Metaphases were dropped on slides and aged overnight. Slides were rinsed for 10 min in 2× SSC (0.3 mol/L NaCl and 0.03 mol/L sodium citrate, pH 7.0) and then soaked for 20 min in 2.5 mg/mL Hoechst (Sigma B-1155) made in 2× SSC. After rinsing in H2O, a few drops of 2× SSC and a glass coverslip were added. Slides were irradiated for 4 min at 55°C under a UV lamp and stained in 5% Giemsa for 40 min before analysis. All analyses were carried out on blinded samples.
Results and Discussion
We have previously shown that the Rad50S allele and, by extension, the Mre11 complex induce apoptosis via the chronic activation of the DNA damage response pathway governed by the Mre11 complex, ATM, p53, and Chk2 (5). As a consequence, Rad50S/S mice exhibit fatal anemia and bone marrow aplasia associated with HSC depletion (6). Two explanations for the bone marrow failure observed have been considered: First, the widespread hematopoietic attrition in Rad50S/S mice may result in homeostatic stress and lead to precipitous exhaustion of the HSC pool (6). An alternative and nonexclusive interpretation is that chronic DNA damage signaling by the Rad50S allele exerts an intrinsic effect on the HSC compartment, leading to its depletion by apoptosis.
To address this issue, we examined the hematopoietic compartment of 2-week-old Rad50S/S mice. This early time point was necessary because most Rad50S/S mice become severely anemic by 4 weeks of age and moribund by 6 to 8 weeks (6). This outcome is intrinsic to Rad50S/S hematopoietic cells (i.e., not attributable to stromal defects), as Rad50S/S fetal liver-derived HSC do not support hematopoietic differentiation in WT mice, even when transplanted in the presence of WT fetal liver cells (6). Hematopoietic progenitor cells and mature hematopoietic cells are also subject to apoptotic attrition in Rad50S/S mice (5, 6). However, because LSK cells are significantly reduced (>90% at 2 weeks of age) when progenitor (Lin−, c-kit+, Sca-1−) cells from mice of the same age show only a 2-fold reduction in frequency (Fig. 1C), we focused on the LSK cells for this study.
First, we assessed by flow cytometry the frequency of lineage-negative, Sca-1–positive, and c-kit–positive (LSK) cells, a population shown to be enriched in HSCs and multipotent progenitors (20–26). In WT animals, this population confers both short-term and long-term hematopoietic reconstitution of irradiated recipients. Although the bone marrow cellularity of 2-week-old Rad50S/S mice remained 80% to 90% of that of WT littermates (data not shown), the LSK frequency of Rad50S/S was reduced to 8% of WT cells (Fig. 1A and B and Supplementary Fig. S1).
These analyses also revealed that Rad50S/S LSK cells exhibited markedly increased levels of apoptotic cells; only 3.5% of LSK cells in WT bone marrow stained positive for Annexin V, whereas 18.8% of Rad50S/S LSK cells were positive (Fig. 1B and Supplementary Fig. S2). This result shows that the increased apoptosis is intrinsic to the Rad50S/S LSK compartment. In addition, an aberrantly large fraction of Rad50S/S LSK cells were in cycle, as evidenced by elevated Ki-67 and Hoechst double staining in the Rad50S/S LSK population (Fig. 1B and Supplementary Fig. S3). In WT mice 30.6% of LSK cells are quiescent (i.e., Ki-67 and Hoechst double negative), compared with 10.5% in Rad50S/S LSK.
The reduction in Rad50S/S LSK quiescence was observed at 2 weeks of age, before significant depletion of hematopoietic bone marrow cells. This suggested that increased LSK proliferation in Rad50S/S was not a homeostatic response to depletion of more mature hematopoietic cells in the bone marrow. We tested this interpretation by crossing Rad50S/S to Chk2−/−, which blocks apoptosis of hematopoietic cells in Rad50S/S mice (5). We reasoned that impaired apoptosis in Chk2 deficiency would eliminate homeostatic pressure on the LSK population and restore quiescence to normal levels. As expected, the apoptotic fraction of Rad50S/S Chk2−/− LSK cells was reduced to WT levels (Fig. 2A); however, the quiescent fraction of Rad50S/S Chk2−/− cells was unchanged. In Rad50S/S Chk2−/− LSK, 14.4% were Ki-67 and Hoechst double negative (Fig. 2A), a fraction similar to the 10.5% observed in Rad50S/S LSK. The fraction of Ki-67–positive cells returned to WT levels in both Rad50S/S Atm+/− and Rad50S/S Atm−/− mice (Fig. 2B and data not shown). These results strongly support the view that reduced LSK cell quiescence and enhanced apoptosis are cell-intrinsic effects of the Mre11 complex-ATM signaling pathway.
To delineate the relative effect of Rad50S/S on LSK cells versus their progeny, the number or cycling characteristics of LSK cells were manipulated genetically. The cyclin-dependent kinase inhibitors p21 and p27 interdict hematopoietic development primarily in HSCs and hematopoietic progenitor cells, respectively; HSC numbers seem to be elevated by p21 deficiency (27) whereas progenitor pools are expanded by p27 deficiency (28). LSK quiescence was altered by crossing Rad50S/S to mice deficient for the transcription factor myeloid elf-1–like factor (Mef/ELF4). Mef promotes the entry of primitive hematopoietic cells into cycle, and in Mef−/− mice quiescence is markedly enhanced (15). Whereas both p21−/− and Mef−/− mice exhibit increased numbers of HSC, only Mef seems to exert an effect on quiescence (Fig. 4A; refs. 27, 29).
Deficiency of Mef, p21, or p27 increased the survival of Rad50S/S mice (P < 10−4). Whereas only 1.2% of Rad50S/S mice survived past 4 months of age, 15.7% of Rad50S/S p21−/− double mutants and 29.4% of Rad50S/S Mef−/− animals survived beyond 4 months (Fig. 3A and B). p27 deficiency increased Rad50S/S survival to a similar extent as p21 deficiency (Fig. 3C; P < 10−4). Despite the enhanced survival of Rad50S/S double mutant animals, the Rad50S-dependent attrition of committed lymphoid and myeloid precursors was not mitigated in p21−/− and Mef−/− (Supplementary Fig. S4A and B). However, p27 deficiency mitigated Rad50S/S hematopoietic attrition; Rad50S/S p27−/− mice exhibited 3.7-fold the number of pro-B cells and 2.5-fold the number of immature B cells present in Rad50S/S mice (Supplementary Fig. S4C). No effect on pre-B or myeloid cells was observed (Supplementary Fig. S4C). These data indicate that mitigation of the Rad50S/S phenotype can be achieved via expansion of either the HSC pool or the precursor pool.
This interpretation is supported by direct analysis of hematopoietic progenitor cell numbers in 4-week-old Rad50S/S, p27−/−, and Rad50S/S p27−/− mice using methylcellulose CFC assays (27, 28). As previously described (28), p27−/− mice exhibited a 2-fold increase in progenitors over WT (Fig. 3D). Whereas Rad50S/S mice showed a 50-fold decrease in progenitor cell numbers, CFCs were within 5-fold of WT in Rad50S/S p27−/− (Fig. 3D). These data indicate that some rescue of the Rad50S/S phenotype in Rad50S/S p27−/− animals is associated with expansion of the progenitor pool.
Conversely, LSK cell frequencies were elevated in both p21- and Mef-deficient Rad50S/S mice when compared with Rad50S/S, and the extent of the LSK increase correlated with the enhancement in survival (Fig. 4A and Supplementary Fig. S1). Whereas Rad50S/S p21−/− had twice as many LSK cells as Rad50S/S at 2 weeks of age, Rad50S/S Mef−/− showed a 4.3-fold increase (to 36% of that of WT animals; Fig. 4A and Supplementary Fig. S1). A switch from fetal to adult hematopoiesis seems to occur at 4 weeks of age. Previous analyses of Mef−/− C57BL/6 or p21−/− 129/Sv were done on 8- to 12-week-old mice (15, 27) when hematopoiesis is of the adult type, a time frame inaccessible in Rad50S/S mice. Thus, age at the time of analysis of LSK cells, necessitated by the Rad50S/S phenotype, may account for differences between the data presented here and those previously reported for Mef−/− (15) and p21−/−. Moreover, the analysis of p21−/− assessed HSC frequency by colony assay (cobblestone area–forming cell assays) and not by FACS (27).
Having established that increased numbers of LSK cells were correlated with increased survival in Rad50S/S p21−/− and Rad50S/S Mef−/− mice, we examined the effects on the quiescence and apoptotic phenotypes of Rad50S/S. The quiescence of the LSK population of Rad50S/S Mef−/− animals was increased compared with that of Rad50S/S mice (21% versus 10.5%, respectively; Fig. 4B and Supplementary Fig. S3). In contrast, p21 deficiency had no effect on LSK quiescence. In Rad50S/S p21−/− LSK, 91.4% were cycling cells, which was similar to the 89.5% cycling of LSK cells in Rad50S/S mice (Fig. 4B and Supplementary Fig. S3). The effects of p21 and Mef-deficiency on LSK cell quiescence were correlated with the levels of apoptosis. Whereas 5% of WT, p21−/−, and Mef−/− LSK stained positive for Annexin V, 18.8% of Rad50S/S and 19.25% of Rad50S/S p21−/− LSK cells were apoptotic (Fig. 4C and Supplementary Fig. S2). This was reduced to only 4.1% Rad50S/S Mef−/− LSK cells. These results suggest that apoptosis of Rad50S/S LSK is dependent on their entry into the cell cycle. Supporting this view, 2 days of treatment with granulocyte colony-stimulating factor (G-CSF), given to induce HSC entry into cycle (30), obliterated the bone marrow LSK pool in 2-week-old Rad50S/S mice (Fig. 4D). Furthermore, whereas G-CSF treatment did not appreciably alter the frequency or the apoptosis of LSK cells in WT and Mef−/− mice, the LSK pool was markedly reduced in Rad50S/S Mef−/− double mutants, from 0.014% of total bone marrow cells before G-CSF–induced cycling (Fig. 4A) to 0.006% after G-CSF treatment (Fig. 4D). This LSK cell depletion correlated with increased levels of apoptosis (Fig. 4D). These data are consistent with the view that apoptotic attrition of Rad50S/S LSK cells is driven by cell cycle entry.
A striking feature of the Rad50S/S double mutants examined was the frequent occurrence of hematopoietic malignancies: 37.5% of Rad50S/S p21−/−, 30% of Rad50S/S Mef−/−, and 35.7% of Rad50S/S p27−/− animals developed tumors (Supplementary Table S1), whereas none were observed in Mef−/−, p21−/− or p27−/− mice, and in Rad50S/S mice, tumors are exceedingly rare (15–17, 31, 32). Malignancy was restricted to the hematopoietic compartments, with both myeloid and lymphoid neoplasms occurring (data not shown). A similar result was observed previously in Rad50S/S mice that also harbor mutations that attenuate ATM-dependent apoptosis: 12 of 14 Rad50S/S Mre11ATLD1/ATLD1 and 17 of 22 Rad50S/S Chk2−/− mice died with malignancies (ref. 5; Supplementary Table S1), whereas no malignancy was seen in Mre11ATLD1/ATLD1 mice (3) or Chk2−/− mice (19).
These results indicate that the Rad50S allele predisposes to malignancy to a greater extent than previously observed, and suggest the possibility that oncogenic DNA damage accumulates in Rad50S/S cells. We previously proposed that the metabolism of topoisomerase lesions may be impaired in Rad50S/S cells (5). This proposal was primarily based on the fact that removal of the Topo II–like molecule Spo11 from double-strand break ends formed in meiosis is blocked in S. cerevisiae Rad50S mutants (7). Because an aberrantly large fraction of Rad50S/S LSK cells are cycling, it is plausible that the attrition of primitive hematopoietic cells and the predisposition to hematopoietic malignancy result from defective resolution of topoisomerase cleavage complexes.
The ability of Rad50S/S cells to metabolize topoisomerase lesions was tested by treatment with camptothecin and etoposide, which stabilize covalent Topo I and Topo II covalent complexes, respectively (33, 34). Presumably because the baseline level of apoptosis was high, we were unable to detect increased apoptosis in Rad50S/S hematopoietic cells on camptothecin treatment (data not shown). The effects of these drugs on MEFs and ear fibroblasts were examined. Rad50S/S cells were slightly more sensitive to etoposide than WT cells, as measured by colony-forming ability after a 24-hour treatment (Fig. 5A). This subtle difference seems to reflect a defect in processing Topo II lesions, as Rad50S/S were not sensitive to ICRF-193 (Fig. 5B), a catalytic inhibitor that blocks the formation of the Topo II cleavage complex (35). Rad50S/S cells were markedly more sensitive to camptothecin (Fig. 5C). The increased sensitivity was not a consequence of defective cell cycle arrest; both WT and Rad50S/S cells arrested in S phase and at the G2 phase of the cell cycle on treatment with camptothecin (data not shown).
Consistent with their relative effects on colony-forming ability, acute exposure of Rad50S/S cells to camptothecin, but not etoposide, increased the induction of chromosome aberrations (Fig. 6A and Supplementary Fig. S5). Cells were treated briefly (2 hours) with etoposide or camptothecin, and mitotic spreads prepared 4 to 6 hours later. In this way, metaphase cells would have been in S phase during drug treatment. Whereas 79% of WT metaphases exhibited no aberrations after a 2-hour treatment with camptothecin, only 59% were free of aberrations in Rad50S/S cells (Fig. 6A; P < 10−3). Moreover, the spectrum of aberrations differed significantly. Of the aberrations present in WT cells, 65% were breaks and chromatid fragments, whereas the other 35% were fusions and exchanges (Fig. 6B). In contrast, the distribution was reversed in Rad50S/S cells, with 64% of aberrations being fusions and exchanges, and 36% breaks and fragments (Fig. 6B). Telomere FISH analysis was used to distinguish short-arm exchanges from telomeric fusions (Fig. 6C). Eighty percent of the aberrations scored by FISH in Rad50S/S cells were short-arm exchanges, whereas only end fusions were present in WT cells (Fig. 6C).
This spectrum of aberrations suggests that camptothecin-stabilized Topo I cleavage complexes induce recombination in Rad50S/S. This interpretation predicted that camptothecin treatment of Rad50S/S cells would induce increased levels of SCE. This prediction was met, as the SCE frequency induced by camptothecin was enhanced in Rad50S/S compared with WT cells (1.055 versus 0.559 SCE/chromosome, respectively; Fig. 6D). In this context, it is noteworthy that lymphomas arising in Rad50S/S p53−/− mice exhibited a complex spectrum of nonclonal chromosomal aberrations (6), consistent with the possibility that increased levels of chromosome rearrangement are induced by the Rad50S allele. Collectively, these results indicate that the Rad50S mutation impairs the processing of topoisomerase cleavage complexes, and suggest that accumulation of this form of DNA damage in Rad50S/S cells markedly predisposes to both apoptosis and malignancy.
This study shows a role for the Mre11 complex in the repair of topoisomerase-associated DNA damage in mammalian cells. In S. cerevisiae, this function has been suggested for Topo I lesions by the extreme cytostatic effects of camptothecin in Mre11 complex nuclease–deficient mutants, as well as from genetic interactions with mutations affecting enzymes such as tyrosyl-DNA-phosphodiesterase that participate in the resolution of the Topo I-DNA linkage (36). Evidence for a repair pathway in S. cerevisiae and mammals dedicated to the resolution of Topo II lesions has recently emerged (7). The observation of Rad50S/S etoposide sensitivity presented here suggests that the Mre11 complex contributes to this pathway (Fig. 5A), consistent with the requirement for the Mre11 nuclease for the removal of Spo11 in meiosis.
In addition, we have established that chronic Mre11 complex–dependent DNA damage signaling in Rad50S/S mice impairs the quiescence of LSK cells and triggers apoptosis. The effect is cell-intrinsic and does not seem to reflect a homeostatic response to the reduced presence of more mature hematopoietic cells in Rad50S/S mice. Hence, the effect of the Mre11 complex-ATM–dependent pathway on HSC cycling starkly contrasts the effect of this pathway in most cells where cycling is suppressed in response to DNA damage rather than enhanced. This effect of the Rad50S allele is not restricted to hematopoietic cells because apoptotic loss of spermatogenic cells and gut epithelia with the same genetic dependencies has been observed (5, 6, 37).
This paradoxical outcome may serve to effectively preserve the integrity of primitive hematopoietic components. In this scenario, entry of HSCs experiencing DNA damage into the cell cycle could increase the likelihood that nonmutagenic DNA repair such as homologous recombination will occur. Entry into S phase would provide a sister chromatid for this mode of repair, and thus could not occur in quiescent cells. Entry into the cell cycle may also increase the efficiency with which apoptosis is induced, thereby facilitating the culling of damaged HSCs from the pool. The observed effect of Rad50S on HSC quiescence raises the possibility that compounds mimicking the Rad50S effect could be used to induce cycling in quiescent cells that carry oncogenic mutations and thus render them more sensitive to cytotoxic chemotherapies.
Finally, we found that p21 and p27 deficiencies promote malignancy in Rad50S/S mice to an extent similar to mutations that impair ATM signaling and apoptosis (5). It is unlikely that ATM regulation is affected by loss of p21 or p27. Thus, the tumor-suppressive effects of p21 and p27 are likely to be via their regulation of hematopoietic cell growth and differentiation. However, recent data show that p27 suppresses prostate cancer independently of its effect on cell cycle regulation. It has been proposed that genome stability, as well as apoptosis, may be affected by p27 (38, 39). The tumor outcome in Rad50S/S Mef−/− is more complex, but is also likely to reflect its influence on differentiation. In ovarian tissues, Mef also functions as an oncogene that drives proliferation when overexpressed or limits proliferation when depleted (40). In Rad50S/S mice, the effect of Mef deficiency on quiescence rescues the LSK cells from elimination, but as it has not been shown to function as a tumor suppressor, the tumors formed in Rad50S/S Mef−/− animals are likely to result from Rad50S-associated oncogenic mutations. Whether dependent or independent of their effects on cell growth, our data underscore the role of cell cycle regulators (including Mef, p21, and p27) in the suppression of hematopoietic malignancy.
Note: Supplementary data for this article are available at Cancer Research Online (http://cancerres.aacrjournals.org/).
Acknowledgments
Grant support: NIH grants GM56888 and GM59413 and the Joel and Joan Smilow Initiative (J.H.J. Petrini), Department of Energy grant DE-FG02-99ER62859 (W.F. Morgan), and NIH grants R01-DK52208 and R01-DK52621 (S.D. Nimer).
The costs of publication of this article were defrayed in part by the payment of page charges. This article must therefore be hereby marked advertisement in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.
We thank Andy Koff, Mark Frattini, and the members of our labs for the careful reading of the manuscript, and Daniel Lacorazza for his help with the stem cell assays.