Chk2 suppresses the oncogenic potential of DNA replication-associated DNA damage

The Mre11 complex (Mre11, Rad50, and Nbs1) and Chk2 have been implicated in the DNA-damage response, an inducible process required for the suppression of malignancy. The Mre11 complex is predominantly required for repair and checkpoint activation in S phase, whereas Chk2 governs apoptosis. We examined the relationship between the Mre11 complex and Chk2 in the DNA-damage response via the establishment of Nbs1(DeltaB/DeltaB) Chk2(-/-) and Mre11(ATLD1/ATLD1) Chk2(-/-) mice. Chk2 deficiency did not modify the checkpoint defects or chromosomal instability of Mre11 complex mutants; however, the double-mutant mice exhibited synergistic defects in DNA-damage-induced p53 regulation and apoptosis. Nbs1(DeltaB/DeltaB) Chk2(-/-) and Mre11(ATLD1/ATLD1) Chk2(-/-) mice were also predisposed to tumors. In contrast, DNA-PKcs-deficient mice, in which G1-specific chromosome breaks are present, did not exhibit synergy with Chk2(-/-) mutants. These data suggest that Chk2 suppresses the oncogenic potential of DNA damage arising during S and G2 phases of the cell cycle.     

Double Strand Break Metabolism and Cancer Susceptibility: Lessons from the Mre11 Complex

Hypomorphic mutants affecting the Mre11 complex components Mre11 (Mre11ATLD1/ATLD1) and Nbs1 (Nbs1?B/?B) have been established in the mouse. These mutations recapitulate those inherited in human chromosome fragility syndromes, the ataxia-telangiectasia like disorder and Nijmegen breakage syndrome. At the cellular level, the human and murine mutants exhibit defects in the intra S and G2/M checkpoints and marked chromosome instability. Whereas these outcomes are associated with predisposition to malignancy in humans, similar predisposition was not observed in either Mre11ATLD1/ATLD1 or Nbs1?B/?B mice. These data demonstrate that chromosome breakage per se is insufficient to significantly enhance the initiation of tumorigenesis. However, these mutations greatly enhanced the risk of malignancy in p53+/- mice. We propose that proper metabolism of chromosome breaks arising during DNA replication is uniquely important for suppressing loss of heterozygosity and thus the penetrance of recessive oncogenic lesions.     

Double strand break metabolism and cancer susceptibility: lessons from the mre11 complex

Hypomorphic mutants affecting the Mre11 complex components Mre11 (Mre11(ATLD1/ATLD1)) and Nbs1 (Nbs1(DeltaB/DeltaB)) have been established in the mouse. These mutations recapitulate those inherited in human chromosome fragility syndromes, the ataxia-telangiectasia like disorder and Nijmegen breakage syndrome. At the cellular level, the human and murine mutants exhibit defects in the intra S and G2/M checkpoints and marked chromosome instability. Whereas these outcomes are associated with predisposition to malignancy in humans, similar predisposition was not observed in either Mre11(ATLD1/ATLD1) or Nbs1(DeltaB/DeltaB) mice. These data demonstrate that chromosome breakage per se is insufficient to significantly enhance the initiation of tumorigenesis. However, these mutations greatly enhanced the risk of malignancy in p53+/- mice. We propose that proper metabolism of chromosome breaks arising during DNA replication is uniquely important for suppressing loss of heterozygosity and thus the penetrance of recessive oncogenic lesions.     

Ataxia-telangiectasia-like disorder (ATLD)-its clinical presentation and molecular basis

Comparison of the clinical and cellular phenotypes of different genomic instability syndromes provides new insights into functional links in the complex network of the DNA damage response. A prominent example of this principle is provided by examination of three such disorders: ataxia-telangiectasia (A-T) caused by lack or inactivation of the ATM protein kinase, which mobilises the cellular response to double strand breaks in the DNA; ataxia-telangiectasia-like disease (ATLD), a result of deficiency of the human Mre11 protein; and the Nijmegen breakage syndrome (NBS), which represents defective Nbs1 protein. Mre11 and Nbs1 are members of the Mre11/Rad50/Nbs1 (MRN) protein complex. MRN and its individual components are involved in different responses to cellular damage induced by ionising radiation and radiomimetic chemicals, including complexing with chromatin and with other damage response proteins, formation of radiation-induced foci, and the induction of different cell cycle checkpoints. The phosphorylation of Nbs1 by ATM would indicate that ATM acts upstream of the MRN complex. Consistent with this were the suggestions that ATM could be activated in the absence of fully functional Nbs1 protein. In contrast, the regulation of some ATM target proteins, e.g. Smc1 requires the MRN complex as well as ATM. Nbs1 may, therefore, be both a substrate for ATM and a mediator of ATM function. Recent studies that indicate a requirement of the MRN complex for proper ATM activation suggest that the relationship between ATM and the MRN complex in the DNA damage response is yet to be fully determined. Despite the fact that both Mre11 and Nbs1 are part of the same MRN complex, deficiency in either protein in humans does not lead to the same clinical picture. This suggests that components of the complex may also act separately.     

The Mre11 complex and the metabolism of chromosome breaks: the importance of communicating and holding things together

The conserved Mre11 complex (Mre11, Rad50, and Nbs1) plays a role in each aspect of chromosome break metabolism. The complex acts as a break sensor and functions in the activation and propagation of signaling pathways that govern cell cycle checkpoint functions in response to DNA damage. In addition, the Mre11 complex influences recombinational DNA repair through promoting recombination between sister chromatids. The Mre11 complex is required for mammalian cell viability but hypomorphic mutants of Mre11 and Nbs1 have been identified in human genetic instability disorders. These hypomorphic mutations, as well as those identified in yeast, have provided a benchmark for establishing mouse models of Mre11 complex deficiency. In addition to consideration of Mre11 complex functions in human cells and yeast, this review will discuss the characterization of mouse models and insight gleaned from those models regarding the metabolism of chromosome breaks. The current picture of break metabolism supports a central role for the Mre11 complex at the interface of chromosome stability and the regulation of cell growth. Further genetic analysis of the Mre11 complex will be an invaluable tool for dissecting its function on an organismal level and determining its role in the prevention of malignancy.     

Regulation of Mre11/Rad50 by Nbs1: effects on nucleotide-dependent DNA binding and association with ataxia-telangiectasia-like disorder mutant complexes

The Mre11/Rad50 complex is a critical component of the cellular response to DNA double-strand breaks, in organisms ranging from archaebacteria to humans. In mammalian cells, Mre11/Rad50 (M/R) associates with a third component, Nbs1, that regulates its activities and is targeted by signaling pathways that initiate DNA damage-induced checkpoint responses. Mutations in the genes that encode Nbs1 and Mre11 are responsible for the human radiation sensitivity disorders Nijmegen breakage syndrome (NBS) and ataxia-telangiectasia-like disorder (ATLD), respectively, which are characterized by defective checkpoint responses and high levels of chromosomal abnormalities. Here we demonstrate nucleotide-dependent DNA binding by the human M/R complex that requires the Nbs1 protein and is specific for double-strand DNA duplexes. Efficient DNA binding is only observed with non-hydrolyzable analogs of ATP, suggesting that ATP hydrolysis normally effects DNA release. The alleles of MRE11 associated with ATLD and the C-terminal Nbs1 polypeptide associated with NBS were expressed with the other components and found to form triple complexes except in the case of ATLD 3/4, which exhibits variability in Nbs1 association. The ATLD 1/2, ATLD 3/4, and p70 M/R/N complexes exhibit nucleotide-dependent DNA binding and exonuclease activity equivalent to the wild-type enzyme, although the ATLD complexes both show reduced activity in endonuclease assays. Sedimentation equilibrium analysis of the recombinant human complexes indicates that Mre11 is a stable dimer, Mre11 and Nbs1 form a 1:1 complex, and both M/R and M/R/N form large multimeric assemblies of approximately 1.2 MDa. Models of M/R/N stoichiometry in light of this and previous data are discussed.     

Independent roles for nibrin and Mre11-Rad50 in the activation and function of Atm

The Atm protein kinase and Mre11-Rad50-nibrin (MRN) complex play an integral role in the cellular response to DNA double-strand breaks. Mutations in Mre11 and nibrin result in the radiosensitivity disorders ataxia-telangiectasia-like disorder (ATLD) and Nijmegen breakage syndrome (NBS), respectively. Cells from ATLD and NBS patients are deficient in activation of the Atm protein kinase and phosphorylation of downstream Atm targets following irradiation. However, the roles of individual MRN complex proteins in Atm function are not clear, because the mutations in NBS and ATLD cells result in global effects on the MRN complex. Previously we showed that the C-terminal 100 amino acids of nibrin were necessary and sufficient to translocate the MRN complex to the nucleus. Here we have taken advantage of this feature of nibrin to create isogenic cell lines lacking either nibrin or Mre11-Rad50 in the nucleus. We found that nuclear expression of Mre11-Rad50, but not nibrin, stimulated Atm activation at early times after low doses of radiation. At later times or higher doses of irradiation, Atm activation was independent of Mre11-Rad50 or nibrin. The requirement of MRN complex proteins for downstream Atm phosphorylation events following irradiation was more complex. Phosphorylation of nibrin and Chk2 by Atm required Mre11-Rad50 expression in the nucleus at early times after irradiation, reflecting the stimulation of Atm activation by Mre11-Rad50. By contrast, autophosphorylation of Chk2 and phosphorylation of Smc1 at Ser-957 was dependent on the MRN complex 60 min after irradiation, even though Atm was activated at that time point. These results indicate an independent role for Mre11-Rad50 in the activation of Atm and suggest nibrin and/or Mre11-Rad50 also act as adaptors for some downstream Atm phosphorylation events.     

The Mre11 Complex and the Response to Dysfunctional Telomeres

In this study, we examine the telomeric functions of the mammalian Mre11 complex by using hypomorphic Mre11 and Nbs1 mutants (Mre11^ATLD1/ATLD1 and Nbs1^ΔB/ΔB, respectively). No telomere shortening was observed in Mre11^ATLD1/ATLD1 cells after extensive passage through culture, and the rate of telomere shortening in telomerase-deficient (Tert^Δ/Δ) Mre11^ATLD1/ATLD1 cells was the same as that in Tert^Δ/Δ alone. Although telomeres from late-passage Mre11^ATLD1/ATLD1 Tert^Δ/Δ cells were as short as those from Tert^Δ/Δ, the incidence of telomere fusions was reduced. This effect on fusions was also evident upon acute telomere dysfunction in Mre11^ATLD1/ATLD1 and Nbs1^ΔB/ΔB cells rendered Trf2 deficient by cre-mediated TRF2 inactivation than in wild-type cells. The residual fusions formed in Mre11 complex mutant cells exhibited a strong tendency toward chromatid fusions, with an almost complete bias for fusion of telomeres replicated by the leading strand. Finally, the response to acute telomere dysfunction was strongly impaired by Mre11 complex hypomorphism, as the formation of telomere dysfunction-induced DNA damage foci was reduced in both cre-infected Mre11^ATLD1/ATLD1 Trf2^F/Δ and Nbs1^ΔB/ΔB Trf2^F/F cells. These data indicate that the Mre11 complex influences the cellular response to telomere dysfunction, reminiscent of its influence on the response to interstitial DNA breaks, and suggest that it may promote telomeric DNA end processing during DNA replication.The Mre11 complex (in mammals, Mre11, Rad50, and Nbs1) plays a central role in the cellular response to DNA double-strand breaks (DSBs). The Mre11 complex acts as a DSB sensor, promoting the activation of ATM-dependent DNA damage signaling pathways, DNA repair, and apoptosis. In addition, the complex plays a direct role in recombinational DNA repair, influencing both homologous recombination and nonhomologous end joining (NHEJ) (39). The Mre11 complex''s diverse functions in the DNA damage response are likely predicated on its physical association with chromatin. In this regard, one of the least-understood roles of the Mre11 complex in mammals is its association with telomeres.In mammals, telomeric DNA consists of double-stranded TTAGGG repeats ending in a single-stranded 3′ G overhang, and an array of telomere binding proteins called the shelterin complex that function to prevent telomeres from being recognized as DNA breaks (33). DNA of the overhang invades the double-stranded telomeric repeat sequence to form a t-loop structure (14, 32). The formation of the t-loop requires the telomere protection and remodeling proteins that make up the shelterin complex (7), and these may also contribute to telomere length regulation by preventing telomerase access to chromosomal ends.Data regarding the role of the Mre11 complex at the telomere have implicated the Mre11 complex in several aspects of telomere maintenance and function. For example, it has been suggested that the Mre11 complex may promote formation of the 3′ telomeric overhang by influencing 5′-to-3′ resection of newly replicated chromosome ends (6). In Saccharomyces cerevisiae, the Mre11 complex recruits the ATM orthologue, Tel1, which is in turn required to recruit telomerase (12, 45). Consequently, Mre11 complex deficiency results in telomere shortening. In mammals, recruitment of telomerase is thought to be regulated primarily by the telomeric protein components TRF1, TPP1, and POT1 (24, 46, 53). However, telomere shortening has also been noted to occur in cell lines from Nijmegen breakage syndrome (NBS) patients in which a hypomorphic Nbs1 allele is expressed, leading to the suggestion that the Mre11 complex may also promote telomerase function in mammals (36). The Mre11 complex associates with telomeres through its interaction with the shelterin component Trf2, apparently in a cell cycle-dependent manner (47, 54). The significance of this physical association is unclear, as genetic depletion of Rad50, a component of the Mre11 complex, does not phenocopy depletion of Trf2 in most respects (1).To examine the function of the Mre11 complex at mammalian telomeres, we established mouse embryonic fibroblasts (MEFs) derived from a mouse expressing the hypomorphic Mre11^ATLD1 allele, crossed to telomerase deficient Tert^Δ/Δ mice (23, 42), and assessed the rate of telomere shortening. Mre11 complex hypomorphism in MEFs did not affect telomere length, irrespective of telomerase status. In Mre11^ATLD1/ATLD1 Tert^Δ/Δ cells, the fusion of eroded telomeres was reduced compared to Tert^Δ/Δ cells with telomeres shortened to the same extent, suggesting that the Mre11 complex is involved in the response to critically short telomeres. This interpretation was supported by data obtained using a conditional Trf2 allele to generate acute telomere dysfunction in Mre11^ATLD1/ATLD1 and Nbs1^ΔB/ΔB cells. Collectively the data support a role for the Mre11 complex in the recognition and signaling of dysfunctional telomeres. The character of fusions arising in cre-infected Mre11^ATLD1/ATLD1 Trf2^F/Δ and Nbs1^ΔB/ΔB Trf2^F/F cells further suggests that the Mre11 complex may influence the processing of chromosome ends following DNA replication en route to t-loop formation.     

The MRE11 GAR motif regulates DNA double-strand break processing and ATR activation

The MRE11/RAD50/NBS1 complex is the primary sensor rapidly recruited to DNA double-strand breaks (DSBs). MRE11 is known to be arginine methylated by PRMT1 within its glycine-arginine-rich (GAR) motif. In this study, we report a mouse knock-in allele of Mre11 that substitutes the arginines with lysines in the GAR motif and generates the MRE11(RK) protein devoid of methylated arginines. The Mre11(RK/RK) mice were hypersensitive to γ-irradiation (IR) and the cells from these mice displayed cell cycle checkpoint defects and chromosome instability. Moreover, the Mre11(RK/RK) MEFs exhibited ATR/CHK1 signaling defects and impairment in the recruitment of RPA and RAD51 to the damaged sites. The M(RK)RN complex formed and localized to the sites of DNA damage and normally activated the ATM pathway in response to IR. The M(RK)RN complex exhibited exonuclease and DNA-binding defects in vitro responsible for the impaired DNA end resection and ATR activation observed in vivo in response to IR. Our findings provide genetic evidence for the critical role of the MRE11 GAR motif in DSB repair, and demonstrate a mechanistic link between post-translational modifications at the MRE11 GAR motif and DSB processing, as well as the ATR/CHK1 checkpoint signaling.     

The mre11 nuclease is critical for the sensitivity of cells to chk1 inhibition

The Chk1 kinase is required for the arrest of cell cycle progression when DNA is damaged, and for stabilizing stalled replication forks. As a consequence, many Chk1 inhibitors have been developed and tested for their potential to enhance DNA damage-induced tumor cell killing. However, inhibition of Chk1 alone, without any additional exogenous agent, can be cytotoxic. Understanding the underlying mechanisms of this sensitivity is critical for defining which patients might respond best to therapy with Chk1 inhibitors. We have investigated the mechanism of sensitivity in U2OS osteosarcoma cells. Upon incubation with the Chk1 inhibitor MK-8776, single-stranded DNA regions (ssDNA) and double-strand breaks (DSB) begin to appear within 6 h. These DSB have been attributed to the structure-specific DNA endonuclease, Mus81. The Mre11/Rad50/Nbs1 complex is known to be responsible for the resection of DSB to ssDNA. However, we show that inhibition of the Mre11 nuclease activity leads, not only to a decrease in the amount of ssDNA following Chk1 inhibition, but also inhibits the formation of DSB, suggesting that DSB are a consequence of ssDNA formation. These findings were corroborated by the discovery that Mre11-deficient ATLD1 cells are highly resistant to MK-8776 and form neither ssDNA nor DSB following treatment. However, once complimented with exogenous Mre11, the cells accumulate both ssDNA and DSB when incubated with MK-8776. Our findings suggest that Mre11 provides the link between aberrant activation of Cdc25A/Cdk2 and Mus81. The results highlight a novel role for Mre11 in the production of DSB and may help define which tumors are more sensitive to MK-8776 alone or in combination with DNA damaging agents.     

NBS1 and TRF1 colocalize at promyelocytic leukemia bodies during late S/G2 phases in immortalized telomerase-negative cells. Implication of NBS1 in alternative lengthening of telomeres

Nijmegen breakage syndrome, a chromosomal instability disorder, is characterized in part by cellular hypersensitivity to ionizing radiation. The NBS1 gene product, p95 (NBS1 or nibrin) forms a complex with Rad50 and Mre11. Cells deficient in the formation of this complex are defective in DNA double-strand break repair, cell cycle checkpoint control, and telomere length maintenance. How the NBS1 complex is involved in telomere length maintenance remains unclear. Here we show that the C-terminal region of NBS1 interacts directly with a telomere repeat binding factor, TRF1, by both yeast two-hybrid and in vivo DNA-coimmunoprecipitation assays. NBS1 and Mre11 colocalize with TRF1 at promyelocytic leukemia (PML) nuclear bodies in immortalized telomerase-negative cell lines, but rarely in telomerase-positive cell lines. The translocation of NBS1 to PML bodies occurs specifically during late S to G(2) phases of the cell cycle and coincides with active DNA synthesis in these NBS1-containing PML bodies. These results suggest that NBS1 may be involved in alternative lengthening of telomeres in telomerase-negative immortalized cells.     

Mre11 assembles linear DNA fragments into DNA damage signaling complexes

Mre11/Rad50/Nbs1 complex (MRN) is essential to suppress the generation of double-strand breaks (DSBs) during DNA replication. MRN also plays a role in the response to DSBs created by DNA damage. Hypomorphic mutations in Mre11 (which causes an ataxia-telangiectasia-like disease [ATLD]) and mutations in the ataxia-telangiectasia-mutated (ATM) gene lead to defects in handling damaged DNA and to similar clinical and cellular phenotypes. Using Xenopus egg extracts, we have designed a simple assay to define the biochemistry of Mre11. MRN is required for efficient activation of the DNA damage response induced by DSBs. We isolated a high molecular weight DNA damage signaling complex that includes MRN, damaged DNA molecules, and activated ATM. Complex formation is partially dependent upon Zn²⁺ and requires an intact Mre11 C-terminal domain that is deleted in some ATLD patients. The ATLD truncation can still perform the role of Mre11 during replication. Our work demonstrates the role of Mre11 in assembling DNA damage signaling centers that are reminiscent of irradiation-induced foci. It also provides a molecular explanation for the similarities between ataxia-telangiectasia (A-T) and ATLD.     

Arsenic-induced Mre11 phosphorylation is cell cycle-dependent and defective in NBS cells

Cancer-prone diseases ataxia-telangiectasia (AT), Nijmegen breakage syndrome (NBS) and ataxia-telangiectasia-like disorder (ATLD) are defective in the repair of DNA double-stranded break (DSB). On the other hand, arsenic (As) has been reported to cause DSB and to be involved in the occurrence of skin, lung and bladder cancers. To dissect the repair mechanism of As-induced DSB, wild type, AT and NBS cells were treated with sodium arsenite to study the complex formation and post-translational modification of Rad50/NBS1/Mre11 repair proteins. Our results showed that Mre11 went through cell cycle-dependent phosphorylation upon sodium arsenite treatment and this post-translational modification required NBS1 but not ATM. Defective As-induced Mre11 phosphorylation was rescued by reconstitution with full length NBS1 in NBS cells. Although As-induced Mre11 phosphorylation was not required for Rad50/NBS1/Mre11 complex formation, it might be required for the formation of Rad50/NBS1/Mre11 nuclear foci upon DNA damage.     

Mre11 ATLD17/18 mutation retains Tel1/ATM activity but blocks DNA double-strand break repair

The Mre11 complex (Mre11-Rad50-Nbs1 or MRN) binds double-strand breaks where it interacts with CtIP/Ctp1/Sae2 and ATM/Tel1 to preserve genome stability through its functions in homology-directed repair, checkpoint signaling and telomere maintenance. Here, we combine biochemical, structural and in vivo functional studies to uncover key properties of Mre11-W243R, a mutation identified in two pediatric cancer patients with enhanced ataxia telangiectasia-like disorder. Purified human Mre11-W243R retains nuclease and DNA binding activities in vitro. X-ray crystallography of Pyrococcus furiosus Mre11 indicates that an analogous mutation leaves the overall Mre11 three-dimensional structure and nuclease sites intact but disorders surface loops expected to regulate DNA and Rad50 interactions. The equivalent W248R allele in fission yeast allows Mre11 to form an MRN complex that efficiently binds double-strand breaks, activates Tel1/ATM and maintains telomeres; yet, it causes hypersensitivity to ionizing radiation and collapsed replication forks, increased Rad52 foci, defective Chk1 signaling and meiotic failure. W248R differs from other ataxia telangiectasia-like disorder analog alleles by the reduced stability of its interaction with Rad50 in cell lysates. Collective results suggest a separation-of-function mutation that disturbs interactions amongst the MRN subunits and Ctp1 required for DNA end processing in vivo but maintains interactions sufficient for Tel1/ATM checkpoint and telomere maintenance functions.     

Mre11 dimers coordinate DNA end bridging and nuclease processing in double-strand-break repair

Mre11 forms the core of the multifunctional Mre11-Rad50-Nbs1 (MRN) complex that detects DNA double-strand breaks (DSBs), activates the ATM checkpoint kinase, and initiates homologous recombination (HR) repair of DSBs. To define the roles of Mre11 in both DNA bridging and nucleolytic processing during initiation of DSB repair, we combined small-angle X-ray scattering (SAXS) and crystal structures of Pyrococcus furiosus Mre11 dimers bound to DNA with mutational analyses of fission yeast Mre11. The Mre11 dimer adopts a four-lobed U-shaped structure that is critical for proper MRN complex assembly and for binding and aligning DNA ends. Further, mutations blocking Mre11 endonuclease activity impair cell survival after DSB induction without compromising MRN complex assembly or Mre11-dependant recruitment of Ctp1, an HR factor, to DSBs. These results show how Mre11 dimerization and nuclease activities initiate repair of DSBs and collapsed replication forks, as well as provide a molecular foundation for understanding cancer-causing Mre11 mutations in ataxia telangiectasia-like disorder (ATLD).     

Inactivation of Mre11 does not affect VSG gene duplication mediated by homologous recombination in Trypanosoma brucei

We demonstrate, by gene deletion analysis, that Mre11 has a critical role in maintaining genomic integrity in Trypanosoma brucei. mre11(-/-) null mutant strains exhibited retarded growth but no delay or disruption of cell cycle progression. They showed also a weak hyporecombination phenotype and the accumulation of gross chromosomal rearrangements, which did not involve sequence translocation, telomere loss, or formation of new telomeres. The trypanosome mre11(-/-) strains were hypersensitive to phleomycin, a mutagen causing DNA double strand breaks (DSBs) but, in contrast to mre11(-/-) null mutants in other organisms and T. brucei rad51(-/-) null mutants, displayed no hypersensitivity to methyl methanesulfonate, which causes point mutations and DSBs. Mre11 therefore is important for the repair of chromosomal damage and DSBs in trypanosomes, although in this organism the intersection of repair pathways appears to differ from that in other organisms. Mre11 inactivation appears not to affect VSG gene switching during antigenic variation of a laboratory strain, which is perhaps surprising given the importance of homologous recombination during this process.     

Rad50S alleles of the Mre11 complex: questions answered and questions raised

We find that Rad50S mutations in yeast and mammals exhibit constitutive PIKK (PI3-kinase like kinase)-dependent signaling [T. Usui, H. Ogawa, J.H. Petrini, A DNA damage response pathway controlled by Tel1 and the Mre11 complex. Mol. Cell 7 (2001) 1255-1266.; M. Morales, J.W. Theunissen, C.F. Kim, R. Kitagawa, M.B. Kastan, J.H. Petrini, The Rad50S allele promotes ATM-dependent DNA damage responses and suppresses ATM deficiency: implications for the Mre11 complex as a DNA damage sensor. Genes Dev. 19 (2005) 3043-4354.]. The signaling depends on Mre11 complex functions, consistent with its role as a DNA damage sensor. Rad50S is distinct from hypomorphic mutations of Mre11 and Nbs1 in mammals [M. Morales, J.W. Theunissen, C.F. Kim, R. Kitagawa, M.B. Kastan, J.H. Petrini, The Rad50S allele promotes ATM-dependent DNA damage responses and suppresses ATM deficiency: implications for the Mre11 complex as a DNA damage sensor. Genes Dev. 19 (2005) 3043-3054.; J.P. Carney, R.S. Maser, H. Olivares, E.M. Davis, Le M. Beau, J.R. Yates, III, L. Hays, W.F. Morgan, J.H. Petrini, The hMre11/hRad50 protein complex and Nijmegen breakage syndrome: linkage of double-strand break repair to the cellular DNA damage response. Cell 93 (1998) 477-486.; G.S. Stewart, R.S. Maser, T. Stankovic, D.A. Bressan, M.I. Kaplan, N.G. Jaspers, A. Raams, P.J. Byrd, J.H. Petrini, A.M. Taylor, The DNA double-strand break repair gene hMRE11 is mutated in individuals with an ataxia-telangiectasia-like disorder. Cell 99 (1999) 577-587.; B.R. Williams, O.K. Mirzoeva, W.F. Morgan, J. Lin, W. Dunnick, J.H. Petrini, A murine model of nijmegen breakage syndrome. Curr. Biol. 12 (2002) 648-653.; J.W. Theunissen, M.I. Kaplan, P.A. Hunt, B.R. Williams, D.O. Ferguson, F.W. Alt, J.H. Petrini, Checkpoint failure and chromosomal instability without lymphomagenesis in Mre11(ATLD1/ATLD1) mice. Mol. Cell 12 (2003) 1511-1523.] and the Mre11 complex deficiency in yeast [T. Usui, H. Ogawa, J.H. Petrini, A DNA damage response pathway controlled by Tel1 and the Mre11 complex. Mol. Cell 7 (2001) 1255-1266.; D'D. Amours, S.P. Jackson, The yeast Xrs2 complex functions in S phase checkpoint regulation. Genes Dev. 15 (2001) 2238-49. ; M. Grenon, C. Gilbert, N.F. Lowndes, Checkpoint activation in response to double-strand breaks requires the Mre11/Rad50/Xrs2 complex. Nat. Cell Biol. 3 (2001) 844-847. ] where the signaling is compromised. Herein, we describe evidence for chronic signaling by Rad50S and discuss possible mechanisms.