Disruption of telomere maintenance by depletion of the MRE11/RAD50/NBS1 complex in cells that use alternative lengthening of telomeres

Immortalized human cells are able to maintain their telomeres by telomerase or by a recombination-mediated DNA replication mechanism known as alternative lengthening of telomeres (ALT). We showed previously that overexpression of Sp100 protein can suppress ALT and that this was associated with sequestration of the MRE11/RAD50/NBS1 (MRN) recombination protein complex by Sp100. In the present study, we determined whether MRN proteins are required for ALT activity. ALT cells were depleted of MRN proteins by small hairpin RNA-mediated knockdown, which was maintained for up to 100 population doublings. Knockdown of NBS1 had no effect on the level of RAD50 or MRE11, but knockdown of RAD50 also depleted cells of NBS1, and knockdown of MRE11 depleted cells of all three MRN proteins. Depletion of NBS1, with or without depletion of other members of the complex, resulted in inhibition of ALT-mediated telomere maintenance, as evidenced by decreased numbers of ALT-associated promyelocytic leukemia bodies and decreased telomere length. In some clones there was an initial period of rapid shortening followed by stabilization of telomere length, whereas in others there was continuous shortening at a rate within the reported range for normal human somatic cells lacking a telomere maintenance mechanism. In contrast, depletion of NBS1 in telomerase-positive cells did not result in telomere shortening. A recent study showed that NBS1 was required for the formation of extrachromosomal telomeric circles (Compton, S. A., Choi, J. H., Cesare, A. J., Ozgur, S., and Griffith, J. D. (2007) Cancer Res. 67, 1513-1519), also a marker for ALT. We conclude that the MRN complex, and especially NBS1, is required for the ALT mechanism.     

The role of DNA damage response proteins at telomeres--an "integrative" model

Telomeres are specialized structures at chromosome ends which play the key role in chromosomal end protection. There is increasing evidence that many DNA damage response proteins are involved in telomere maintenance. For example, cells defective in DNA double strand break repair proteins including Ku, DNA-PKcs, RAD51D and the MRN (MRE11/RAD51/NBS1) complex show loss of telomere capping function. Similarly, mouse and human cells defective in ataxia telangiectasia mutated (ATM) have defective telomeres. A total of 14 mammalian DNA damage response proteins have, so far, been implicated in telomere maintenance. Recent studies indicate that three more proteins, namely BRCA1, hRad9 and PARP1 are involved in telomere maintenance. The involvement of a wide range of DNA damage response proteins at telomeres raises an important question: do telomere maintenance mechanisms constitute an integral part of DNA damage response machinery? A model termed the "integrative" model is proposed here to argue in favour of telomere maintenance being an integral part of DNA damage response. The "integrative" model is supported by the observation that a telomeric protein, TRF2, is not confined to its local telomeric environment but it migrates to the sites of DNA breakage following exposure of cells to ionizing radiation. Furthermore, even if telomeres are maintained in a non-canonical way, as in the case of Drosophila, DNA damage response proteins are still involved in telomere maintenance suggesting integration of telomere maintenance mechanisms into the DNA damage response network.     

Rescue of a telomere length defect of Nijmegen breakage syndrome cells requires NBS and telomerase catalytic subunit.

Nijmegen breakage syndrome (NBS) is a rare human disease displaying chromosome instability, radiosensitivity, cancer predisposition, immunodeficiency, and other defects [1, 2]. NBS is complexed with MRE11 and RAD50 in a DNA repair complex [3-5] and is localized to telomere ends in association with TRF proteins [6, 7]. We show that blood cells from NBS patients have shortened telomere DNA ends. Likewise, cultured NBS fibroblasts that exhibit a premature growth cessation were observed with correspondingly shortened telomeres. Introduction of the catalytic subunit of telomerase, TERT, was alone sufficient to increase the proliferative capacity of NBS fibroblasts. However, NBS, but not TERT, restores the capacity of NBS cells to survive gamma irradiation damage. Strikingly, NBS promotes telomere elongation in conjunction with TERT in NBS fibroblasts. These results suggest that NBS is a required accessory protein for telomere extension. Since NBS patients have shortened telomeres, these defects may contribute to the chromosome instability and disease associated with NBS patients.     

MRE11-RAD50-NBS1 and ATM function as co-mediators of TRF1 in telomere length control

Human telomeres are associated with ATM and the protein complex consisting of MRE11, RAD50 and NBS1 (MRN), which are central to maintaining genomic stability. Here we show that when targeted to telomeres, wild-type RAD50 downregulates telomeric association of TRF1, a negative regulator of telomere maintenance. TRF1 binding to telomeres is upregulated in cells deficient in NBS1 or under ATM inhibition. The TRF1 association with telomeres induced by ATM inhibition is abrogated in cells lacking MRE11 or NBS1, suggesting that MRN and ATM function in the same pathway controlling TRF1 binding to telomeres. The ability of TRF1 to interact with telomeric DNA in vitro is impaired by ATM-mediated phosphorylation. We propose that MRN is required for TRF1 phosphorylation by ATM and that such phosphorylation results in the release of TRF1 from telomeres, promoting telomerase access to the ends of telomeres.     

Mystery of DNA repair: the role of the MRN complex and ATM kinase in DNA damage repair

Genomes are subject to a number of exogenous or endogenous DNA-damaging agents that cause DNA double-strand breaks (DSBs). These critical DNA lesions can result in cell death or a wide variety of genetic alterations, including deletions, translocations, loss of heterozygosity, chromosome loss, or chromosome fusions, which enhance genome instability and can trigger carcinogenesis. The cells have developed an efficient mechanism to cope with DNA damages by evolving the DNA repair machinery. There are 2 major DSB repair mechanisms: nonhomologous end joining (NHEJ) and homologous recombination (HR). One element of the repair machinery is the MRN complex, consisting of MRE11, RAD50 and NBN (previously described as NBS1), which is involved in DNA replication, DNA repair, and signaling to the cell cycle checkpoints. A number of kinases, like ATM (ataxia-telangiectasia mutated), ATR (ataxia-telangiectasia and Rad-3-related), and DNA PKcs (DNA protein kinase catalytic subunit), phosphorylate various protein targets in order to repair the damage. If the damage cannot be repaired, they direct the cell to apoptosis. The MRN complex as well as repair kinases are also involved in telomere maintenance and genome stability. The dysfunction of particular elements involved in the repair mechanisms leads to genome instability disorders, like ataxia telangiectasia (A-T), A-T-like disorder (ATLD) and Nijmegen breakage syndrome (NBS). The mutated genes responsible for these disorders code for proteins that play key roles in the process of DNA repair. Here we present a detailed review of current knowledge on the MRN complex, kinases engaged in DNA repair, and genome instability disorders.     

NBS1在DNA断裂损伤反应和维持端粒稳定中的作用

NBS1作为MRE11/RAD50/NBS1复合物的组分之一,是细胞应答DNA损伤的一个关键蛋白质,在DNA双链断裂修复和维持基因组稳定中发挥重要的作用。端粒是染色体末端由DNA重复序列和蛋白质构成的复合体,其独特结构与DNA双链断裂非常相似。最近几年的研究发现NBS1与端粒也有着十分密切的联系。综述了NBS1在DNA损伤反应中的作用,并探讨NBS1参与维持端粒稳定中的分子机制。     

Human RAD50 Deficiency in a Nijmegen Breakage Syndrome-like Disorder

The MRE11/RAD50/NBN (MRN) complex plays a key role in recognizing and signaling DNA double-strand breaks (DSBs). Hypomorphic mutations in NBN (previously known as NBS1) and MRE11A give rise to the autosomal-recessive diseases Nijmegen breakage syndrome (NBS) and ataxia-telangiectasia-like disorder (ATLD), respectively. To date, no disease due to RAD50 deficiency has been described. Here, we report on a patient previously diagnosed as probably having NBS, with microcephaly, mental retardation, ‘bird-like’ face, and short stature. At variance with this diagnosis, she never had severe infections, had normal immunoglobulin levels, and did not develop lymphoid malignancy up to age 23 years. We found that she is compound heterozygous for mutations in the RAD50 gene that give rise to low levels of unstable RAD50 protein. Cells from the patient were characterized by chromosomal instability; radiosensitivity; failure to form DNA damage-induced MRN foci; and impaired radiation-induced activation of and downstream signaling through the ATM protein, which is defective in the human genetic disorder ataxia-telangiectasia. These cells were also impaired in G1/S cell-cycle-checkpoint activation and displayed radioresistant DNA synthesis and G2-phase accumulation. The defective cellular phenotype was rescued by wild-type RAD50. In conclusion, we have identified and characterized a patient with a RAD50 deficiency that results in a clinical phenotype that can be classified as an NBS-like disorder (NBSLD).     

The importance of making ends meet: mutations in genes and altered expression of proteins of the MRN complex and cancer

The MRN protein complex, consisting of MRE1, RAD50 and NBS1, plays a crucial role in sensing DNA double-strand breaks (DSBs), and it is involved in cell cycle control. This makes the MRN complex an important guard of genome stability. Hypomorphic mutations in NBS1 result in the Nijmegen breakage syndrome (NBS), which is characterized by, among other things, an increased predisposition to malignancies, especially leukemia/lymphoma. Relatives of NBS patients carrying heterozygous mutations are also more prone to cancer development. This review summarizes several studies searching for associations between heterozygous mutations in NBS1, MRE11, and RAD50 and cancer and examining the levels of expression of proteins coded by these genes in tumor tissues. The results indicate that both decreased and increased expression of NBS1 may contribute to tumorigenesis, whereas overexpressed RAD50 has an anti-tumoric effect. MRE11 and RAD50 are also affected in tumors with microsatellite instability. However, the outcomes of association studies, which concerned primarily lymphomas/leukemias and breast cancer, were inconclusive. Heterozygous NBS1 mutations and molecular variants 657del5, I171V, R215W and E185Q were most commonly analyzed. Among these, an association with cancer was found most frequently for 657del5 (in leukemia/lymphoma and breast cancer) and I171V (in leukemia, breast, head and neck and colorectal cancers); however, other studies gave contradictory results. For other NBS1 as well as MRE11 and RAD50 variants, too little data were available to assess their role in cancer risk. Overall, the results suggest that heterozygous MRN complex mutations and molecular variants may contribute only to a limited fraction of tumors. This may be caused by several factors: various frequencies of the variants in specific populations, different criteria used for selection of control groups, possible effects of environmental factors, and potential interactions with variants of other low-risk genes. These issues, as well as the impact of the alterations on protein function, need to be addressed in future studies.     

Recruitment of NBS1 into PML oncogenic domains via interaction with SP100 protein

Nijmegen breakage syndrome (NBS) is an autosomal recessive disorder characterized by microcephaly, chromosomal instability, radiation sensitivity, and an increased incidence of malignancies. NBS1, the protein responsible for NBS, forms a complex with MRE11 and RAD50, and plays a vital role in DNA repair, cell cycle checkpoint, and telomere maintenance. Here, we show that a BRCA carboxyl terminus (BRCT) domain-containing region of NBS1 interacts with a nuclear dots-associated protein, SP100. The SP100 and NBS1 proteins co-localized in PODs and APBs in normal human fibroblast MRC5 and ALT line VA13 at G2 phase, respectively. Introduction of PML and SP100 into NT2 cells, which express no detectable amount of PML or SP100 proteins, resulted in localization of NBS1 in ectopically expressed PODs. These results indicate that NBS1 is recruited into PODs via interaction with SP100 protein. Thus, interaction between the NBS1 and SP100 proteins may be involved in genomic stability and telomere maintenance.     

The role of NBS1 in DNA double strand break repair, telomere stability, and cell cycle checkpoint control

The genomes of eukaryotic cells are under continuous assault by environmental agents and endogenous metabolic byproducts. Damage induced in DNA usually leads to a cascade of cellular events, the DNA damage response. Failure of the DNA damage response can lead to development of malignancy by reducing the efficiency and fidelity of DNA repair. The NBS1 protein is a component of the MRE11/RAD50/NBS 1 complex （MRN） that plays a critical role in the cellular response to DNA damage and the maintenance of chromosomal integrity. Mutations in the NBS1 gene are responsible for Nijmegen breakage syndrome （NBS）, a hereditary disorder that imparts an increased predisposition to development of malignancy. The phenotypic characteristics of cells isolated from NBS patients point to a deficiency in the repair of DNA double strand breaks. Here, we review the current knowledge of the role of NBS1 in the DNA damage response. Emphasis is placed on the role of NBS1 in the DNA double strand repair, modulation of the DNA damage sensing and signaling, cell cycle checkpoint control and maintenance oftelomere stability.     

SIRT1 regulates the function of the Nijmegen breakage syndrome protein

MRE11-RAD50-NBS1 (MRN) is a conserved nuclease complex that exhibits properties of a DNA damage sensor and is critical in regulating cellular responses to DNA double-strand breaks. NBS1, which is mutated in the human genetic disease Nijmegen breakage syndrome, serves as the regulatory subunit of MRN. Phosphorylation of NBS1 by the ATM kinase is necessary for both activation of the S phase checkpoint and for efficient DNA damage repair response. Here, we report that NBS1 is an acetylated protein and that the acetylation level is tightly regulated by the SIRT1 deacetylase. SIRT1 associates with the MRN complex and, importantly, maintains NBS1 in a hypoacetylated state, which is required for ionizing radiation-induced NBS1 Ser343 phosphorylation. Our results demonstrate the presence of crosstalk between two different posttranslational modifications in NBS1 and strongly suggest that deacetylation of NBS1 by SIRT1 plays a key role in the dynamic regulation of the DNA damage response and in the maintenance of genomic stability.     

Suppression of alternative lengthening of telomeres by Sp100-mediated sequestration of the MRE11/RAD50/NBS1 complex

Approximately 10% of cancers overall use alternative lengthening of telomeres (ALT) instead of telomerase to prevent telomere shortening, and ALT is especially common in astrocytomas and various types of sarcomas. The hallmarks of ALT in telomerase-negative cancer cells include a unique pattern of telomere length heterogeneity, rapid changes in individual telomere lengths, and the presence of ALT-associated promyelocytic leukemia bodies (APBs) containing telomeric DNA and proteins involved in telomere binding, DNA replication, and recombination. The ALT mechanism appears to involve recombination-mediated DNA replication, but the molecular details are largely unknown. In telomerase-null Saccharomyces cerevisiae, an analogous survivor mechanism is dependent on the RAD50 gene. We demonstrate here that overexpression of Sp100, a constituent of promyelocytic leukemia nuclear bodies, sequestered the MRE11, RAD50, and NBS1 recombination proteins away from APBs. This resulted in repression of the ALT mechanism, as evidenced by progressive telomere shortening at 121 bp per population doubling, a rate within the range found in telomerase-negative normal cells, suppression of rapid telomere length changes, and suppression of APB formation. Spontaneously generated C-terminally truncated Sp100 that did not sequester the MRE11, RAD50, and NBS1 proteins failed to inhibit ALT. These findings identify for the first time proteins that are required for the ALT mechanism.     

ATM-dependent phosphorylation of MRE11 controls extent of resection during homology directed repair by signalling through Exonuclease 1

The MRE11/RAD50/NBS1 (MRN) complex plays a central role as a sensor of DNA double strand breaks (DSB) and is responsible for the efficient activation of ataxia-telangiectasia mutated (ATM) kinase. Once activated ATM in turn phosphorylates RAD50 and NBS1, important for cell cycle control, DNA repair and cell survival. We report here that MRE11 is also phosphorylated by ATM at S676 and S678 in response to agents that induce DNA DSB, is dependent on the presence of NBS1, and does not affect the association of members of the complex or ATM activation. A phosphosite mutant (MRE11S676AS678A) cell line showed decreased cell survival and increased chromosomal aberrations after radiation exposure indicating a defect in DNA repair. Use of GFP-based DNA repair reporter substrates in MRE11S676AS678A cells revealed a defect in homology directed repair (HDR) but single strand annealing was not affected. More detailed investigation revealed that MRE11S676AS678A cells resected DNA ends to a greater extent at sites undergoing HDR. Furthermore, while ATM-dependent phosphorylation of Kap1 and SMC1 was normal in MRE11S676AS678A cells, there was no phosphorylation of Exonuclease 1 consistent with the defect in HDR. These results describe a novel role for ATM-dependent phosphorylation of MRE11 in limiting the extent of resection mediated through Exonuclease 1.     

A divalent FHA/BRCT‐binding mechanism couples the MRE11–RAD50–NBS1 complex to damaged chromatin

The MRE11–RAD50–NBS1 (MRN) complex accumulates at sites of DNA double‐strand breaks in large chromatin domains flanking the lesion site. The mechanism of MRN accumulation involves direct binding of the Nijmegen breakage syndrome 1 (NBS1) subunit to phosphorylated mediator of the DNA damage checkpoint 1 (MDC1), a large nuclear adaptor protein that interacts directly with phosphorylated H2AX. NBS1 contains an FHA domain and two BRCT domains at its amino terminus. Here, we show that both of these domains participate in the interaction with phosphorylated MDC1. Point mutations in key amino acid residues of either the FHA or the BRCT domains compromise the interaction with MDC1 and lead to defects in MRN accumulation at sites of DNA damage. Surprisingly, only mutation in the FHA domain, but not in the BRCT domains, yields a G2/M checkpoint defect, indicating that MDC1‐dependent chromatin accumulation of the MRN complex at sites of DNA breaks is not required for G2/M checkpoint activation.     

The Nijmegen breakage syndrome gene and its role in genome stability

NBS1 is the key regulator of the RAD50/MRE11/NBS1 (R/M/N) protein complex, a sensor and mediator for cellular DNA damage response. NBS1 potentiates the enzymatic activity of MRE11 and directs the R/M/N complex to sites of DNA damage, where it forms nuclear foci by interacting with phosphorylated H2AX. The R/M/N complex also activates the ATM kinase, which is a major kinase involved in the activation of DNA damage signal pathways. The ATM requires the R/M/N complex for its own activation following DNA damage, and for conformational change to develop a high affinity for target proteins. In addition, association of NBS1 with PML, the promyelocytic leukemia protein, is required to form nuclear bodies, which have various functions depending on their location and composition. These nuclear bodies function not only in response to DNA damage, but are also involved in telomere maintenance when they are located on telomeres. In this review, we describe the role of NBS1 in the maintenance of genetic stability through the activation of cell-cycle checkpoints, DNA repair, and protein relocation.     

The MRN complex promotes DNA repair by homologous recombination and restrains antigenic variation in African trypanosomes

Homologous recombination dominates as the major form of DNA repair in Trypanosoma brucei, and is especially important for recombination of the subtelomeric variant surface glycoprotein during antigenic variation. RAD50, a component of the MRN complex (MRE11, RAD50, NBS1), is central to homologous recombination through facilitating resection and governing the DNA damage response. The function of RAD50 in trypanosomes is untested. Here we report that RAD50 and MRE11 are required for RAD51-dependent homologous recombination and phosphorylation of histone H2A following a DNA double strand break (DSB), but neither MRE11 nor RAD50 substantially influence DSB resection at a chromosome-internal locus. In addition, we reveal intrinsic separation-of-function between T. brucei RAD50 and MRE11, with only RAD50 suppressing DSB repair using donors with short stretches of homology at a subtelomeric locus, and only MRE11 directing DSB resection at the same locus. Finally, we show that loss of either MRE11 or RAD50 causes a greater diversity of expressed VSG variants following DSB repair. We conclude that MRN promotes stringent homologous recombination at subtelomeric loci and restrains antigenic variation.     

A glycine-arginine domain in control of the human MRE11 DNA repair protein

Human MRE11 is a key enzyme in DNA double-strand break repair and genome stability. Human MRE11 bears a glycine-arginine-rich (GAR) motif that is conserved among multicellular eukaryotic species. We investigated how this motif influences MRE11 function. Human MRE11 alone or a complex of MRE11, RAD50, and NBS1 (MRN) was methylated in insect cells, suggesting that this modification is conserved during evolution. We demonstrate that PRMT1 interacts with MRE11 but not with the MRN complex, suggesting that MRE11 arginine methylation occurs prior to the binding of NBS1 and RAD50. Moreover, the first six methylated arginines are essential for the regulation of MRE11 DNA binding and nuclease activity. The inhibition of arginine methylation leads to a reduction in MRE11 and RAD51 focus formation on a unique double-strand break in vivo. Furthermore, the MRE11-methylated GAR domain is sufficient for its targeting to DNA damage foci and colocalization with gamma-H2AX. These studies highlight an important role for the GAR domain in regulating MRE11 function at the biochemical and cellular levels during DNA double-strand break repair.     

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.     

Functional human telomeres are recognized as DNA damage in G2 of the cell cycle

Telomeres have to be distinguished from DNA breaks that initiate a DNA damage response. Proteins involved in the DNA damage response have previously been found at telomeres in transformed cells; however, the importance of these factors for telomere function has not been understood. Here, we show that telomeres of telomerase-negative primary cells recruit Mre11, phosphorylated NBS1, and ATM in every G2 phase of the cell cycle. This recruitment correlates with a partial release of telomeric POT1; moreover, telomeres were found to be accessible to modifying enzymes at this time in the cell cycle, suggesting that they are unprotected. Degradation of the MRN complex, as well as inhibition of ATM, led to telomere dysfunction. Consequentially, we propose that a localized DNA damage response at telomeres after replication is essential for recruiting the processing machinery that promotes formation of a chromosome end protection complex.     

MRE11 complex links RECQ5 helicase to sites of DNA damage

RECQ5 DNA helicase suppresses homologous recombination (HR) possibly through disruption of RAD51 filaments. Here, we show that RECQ5 is constitutively associated with the MRE11–RAD50–NBS1 (MRN) complex, a primary sensor of DNA double-strand breaks (DSBs) that promotes DSB repair and regulates DNA damage signaling via activation of the ATM kinase. Experiments with purified proteins indicated that RECQ5 interacts with the MRN complex through both MRE11 and NBS1. Functional assays revealed that RECQ5 specifically inhibited the 3′→5′ exonuclease activity of MRE11, while MRN had no effect on the helicase activity of RECQ5. At the cellular level, we observed that the MRN complex was required for the recruitment of RECQ5 to sites of DNA damage. Accumulation of RECQ5 at DSBs was neither dependent on MDC1 that mediates binding of MRN to DSB-flanking chromatin nor on CtIP that acts in conjunction with MRN to promote resection of DSBs for repair by HR. Collectively, these data suggest that the MRN complex recruits RECQ5 to sites of DNA damage to regulate DNA repair.