EXO1 is critical for embryogenesis and the DNA damage response in mice with a hypomorphic Nbs1 allele

The maintenance of genome stability is critical for the suppression of diverse human pathologies that include developmental disorders, premature aging, infertility and predisposition to cancer. The DNA damage response (DDR) orchestrates the appropriate cellular responses following the detection of lesions to prevent genomic instability. The MRE11 complex is a sensor of DNA double strand breaks (DSBs) and plays key roles in multiple aspects of the DDR, including DNA end resection that is critical for signaling and DNA repair. The MRE11 complex has been shown to function both upstream and in concert with the 5′-3′ exonuclease EXO1 in DNA resection, but it remains unclear to what extent EXO1 influences DSB responses independently of the MRE11 complex. Here we examine the genetic relationship of the MRE11 complex and EXO1 during mammalian development and in response to DNA damage. Deletion of Exo1 in mice expressing a hypomorphic allele of Nbs1 leads to severe developmental impairment, embryonic death and chromosomal instability. While EXO1 plays a minimal role in normal cells, its loss strongly influences DNA replication, DNA repair, checkpoint signaling and damage sensitivity in NBS1 hypomorphic cells. Collectively, our results establish a key role for EXO1 in modulating the severity of hypomorphic MRE11 complex mutations.     

Exome Capture Reveals ZNF423 and CEP164 Mutations, Linking Renal Ciliopathies to DNA Damage Response Signaling

Nephronophthisis-related ciliopathies (NPHP-RC) are degenerative recessive diseases that affect kidney, retina, and brain. Genetic defects in NPHP gene products that localize to cilia and centrosomes defined them as "ciliopathies." However, disease mechanisms remain poorly understood. Here, we identify by whole-exome resequencing, mutations of MRE11, ZNF423, and CEP164 as causing NPHP-RC. All three genes function within the DNA damage response (DDR) pathway. We demonstrate that, upon induced DNA damage, the NPHP-RC proteins ZNF423, CEP164, and NPHP10 colocalize to nuclear foci positive for TIP60, known to activate ATM at sites?of DNA damage. We show that knockdown of CEP164 or ZNF423 causes sensitivity to DNA damaging agents and that cep164 knockdown in zebrafish results in dysregulated DDR and an NPHP-RC phenotype. Our findings link degenerative diseases of the kidney and retina, disorders of increasing prevalence, to mechanisms of DDR. PAPERFLICK:     

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.     

High resolution imaging of changes in the structure and spatial organization of chromatin, γ-H2A.X and the MRN complex within etoposide-induced DNA repair foci

The focal accumulation of DNA repair factors, including the MRE11/Rad50/NBS1 (MRN) complex and the phospho-histone variant γ-H2A.X, is a key cytological feature of the DNA damage response (DDR). Although these foci have been extensively studied by light microscopy, there is comparatively little known regarding their ultrastructure. Using correlative light microscopy and electron spectroscopic imaging (LM/ESI) we have characterized the ultrastructure of chromatin and DNA repair foci within the nuclei of normal human fibroblasts in response to DNA double-strand breaks (DSBs). The induction of DNA DSBs by etoposide leads to a global decrease in chromatin density, which is accompanied by the formation of invaginations of the nuclear envelope as revealed by live-cell microscopy. Using LM/ESI and the immunogold localization of γ-H2A.X and MRE11 within repair foci, we also observed decondensed 10nm chromatin fibers within repair foci and the accumulation of large non-chromosomal protein complexes over three hours recovery from etoposide. At 18 h after etoposide treatment, we observed a close juxtapositioning of PML nuclear bodies and late repair foci of γ-H2A.X, which exhibited a highly organized chromatin arrangement distinct from earlier repair foci. Finally, the dual immunogold labeling of MRE11 with either γ-H2A.X or NBS1 revealed that γ-H2A.X and the MRN complex are sub-compartmentalized within repair foci at the sub-micron scale. Together these data provide the first ultrastructural comparison of γ-H2A.X and MRN DNA repair foci, which are structurally dynamic over time and strikingly similar in organization.     

Phospho-dependent interactions between NBS1 and MDC1 mediate chromatin retention of the MRN complex at sites of DNA damage

Mammalian cells respond to DNA double-strand breaks (DSBs) by recruiting DNA repair and cell-cycle checkpoint proteins to such sites. Central to these DNA damage response (DDR) events is the DNA damage mediator protein MDC1. MDC1 interacts with several DDR proteins, including the MRE11–RAD50–NBS1 (MRN) complex. Here, we show that MDC1 is phosphorylated on a cluster of conserved repeat motifs by casein kinase 2 (CK2). Moreover, we establish that this phosphorylation of MDC1 promotes direct, phosphorylation-dependent interactions with NBS1 in a manner that requires the closely apposed FHA and twin BRCT domains in the amino terminus of NBS1. Finally, we show that these CK2-targeted motifs in MDC1 are required to mediate NBS1 association with chromatin-flanking sites of unrepaired DSBs. These findings provide a molecular explanation for the MDC1–MRN interaction and yield insights into how MDC1 coordinates the focal assembly and activation of several DDR factors in response to DNA damage.     

Nuclear GIT2 Is an ATM Substrate and Promotes DNA Repair

Insults to nuclear DNA induce multiple response pathways to mitigate the deleterious effects of damage and mediate effective DNA repair. G-protein-coupled receptor kinase-interacting protein 2 (GIT2) regulates receptor internalization, focal adhesion dynamics, cell migration, and responses to oxidative stress. Here we demonstrate that GIT2 coordinates the levels of proteins in the DNA damage response (DDR). Cellular sensitivity to irradiation-induced DNA damage was highly associated with GIT2 expression levels. GIT2 is phosphorylated by ATM kinase and forms complexes with multiple DDR-associated factors in response to DNA damage. The targeting of GIT2 to DNA double-strand breaks was rapid and, in part, dependent upon the presence of H2AX, ATM, and MRE11 but was independent of MDC1 and RNF8. GIT2 likely promotes DNA repair through multiple mechanisms, including stabilization of BRCA1 in repair complexes; upregulation of repair proteins, including HMGN1 and RFC1; and regulation of poly(ADP-ribose) polymerase activity. Furthermore, GIT2-knockout mice demonstrated a greater susceptibility to DNA damage than their wild-type littermates. These results suggest that GIT2 plays an important role in MRE11/ATM/H2AX-mediated DNA damage responses.     

Discordance between phosphorylation and recruitment of 53BP1 in response to DNA double-strand breaks

During the DNA damage response (DDR), chromatin modifications contribute to localization of 53BP1 to sites of DNA double-strand breaks (DSBs). 53BP1 is phosphorylated during the DDR, but it is unclear whether phosphorylation is directly coupled to chromatin binding. In this study, we used human diploid fibroblasts and HCT116 tumor cells to study 53BP1 phosphorylation at Serine-25 and Serine-1778 during endogenous and exogenous DSBs (DNA replication and whole-cell or sub-nuclear microbeam irradiation, respectively). In non-stressed conditions, endogenous DSBs in S-phase cells led to accumulation of 53BP1 and γH2AX into discrete nuclear foci. Only the frank collapse of DNA replication forks following hydroxyurea treatment initiated 53BP1^Ser25 and 53BP1^Ser1778 phosphorylation. In response to exogenous DSBs, 53BP1^Ser25 and 53BP1^Ser1778 phosphoforms localized to sites of initial DSBs in a cell cycle-independent manner. 53BP1 phosphoforms also localized to late residual foci and associated with PML-NBs during IR-induced senescence. Using isogenic cell lines and small-molecule inhibitors, we observed that DDR-induced 53BP1 phosphorylation was dependent on ATM and DNA-PKcs kinase activity but independent of MRE11 sensing or RNF168 chromatin remodeling. However, loss of RNF168 blocked recruitment of phosphorylated 53BP1 to sites of DNA damage. Our results uncouple 53BP1 phosphorylation from DSB localization and support parallel pathways for 53BP1 biology during the DDR. As relative 53BP1 expression may be a biomarker of DNA repair capacity in solid tumors, the tracking of 53BP1 phosphoforms in situ may give unique information regarding different cancer phenotypes or response to cancer treatment.     

Chromosomal breakage syndromes and the BRCA1 genome surveillance complex

Chromosomal instability can occur when the DNA damage response and repair process fails, resulting in syndromes characterized by growth abnormalities, hematopoietic defects, mutagen sensitivity, and cancer predisposition. Mutations in ATM, NBS1, MRE11, BLM, WRN, and FANCD2 are responsible for ataxia telangiectasia (AT), Nijmegen breakage syndrome, AT-like disorder, Bloom and Werner syndrome, and Fanconi anemia group D2, respectively. This diverse group of disorders is thought to be linked through protein interactions with the breast cancer tumor susceptibility gene product, BRCA1. BRCA1 forms a multi-subunit protein complex referred to as the BRCA1-associated genome surveillance complex (BASC), which includes DNA damage repair proteins such as MSH2-MSH6 and MLH1, as well as ATM, NBS1, MRE11, and BLM. Although still controversial, this finding suggests similarities in the pathogenesis of the human chromosome breakage syndromes and a complementary role for each protein in DNA structure surveillance or damage repair.     

DNA Damage Response and Spindle Assembly Checkpoint Function throughout the Cell Cycle to Ensure Genomic Integrity

Errors in replication or segregation lead to DNA damage, mutations, and aneuploidies. Consequently, cells monitor these events and delay progression through the cell cycle so repair precedes division. The DNA damage response (DDR), which monitors DNA integrity, and the spindle assembly checkpoint (SAC), which responds to defects in spindle attachment/tension during metaphase of mitosis and meiosis, are critical for preventing genome instability. Here we show that the DDR and SAC function together throughout the cell cycle to ensure genome integrity in C. elegans germ cells. Metaphase defects result in enrichment of SAC and DDR components to chromatin, and both SAC and DDR are required for metaphase delays. During persistent metaphase arrest following establishment of bi-oriented chromosomes, stability of the metaphase plate is compromised in the absence of DDR kinases ATR or CHK1 or SAC components, MAD1/MAD2, suggesting SAC functions in metaphase beyond its interactions with APC activator CDC20. In response to DNA damage, MAD2 and the histone variant CENPA become enriched at the nuclear periphery in a DDR-dependent manner. Further, depletion of either MAD1 or CENPA results in loss of peripherally associated damaged DNA. In contrast to a SAC-insensitive CDC20 mutant, germ cells deficient for SAC or CENPA cannot efficiently repair DNA damage, suggesting that SAC mediates DNA repair through CENPA interactions with the nuclear periphery. We also show that replication perturbations result in relocalization of MAD1/MAD2 in human cells, suggesting that the role of SAC in DNA repair is conserved.     

DNA-PK phosphorylation of RPA32 Ser4/Ser8 regulates replication stress checkpoint activation,fork restart,homologous recombination and mitotic catastrophe

Genotoxins and other factors cause replication stress that activate the DNA damage response (DDR), comprising checkpoint and repair systems. The DDR suppresses cancer by promoting genome stability, and it regulates tumor resistance to chemo- and radiotherapy. Three members of the phosphatidylinositol 3-kinase-related kinase (PIKK) family, ATM, ATR, and DNA-PK, are important DDR proteins. A key PIKK target is replication protein A (RPA), which binds single-stranded DNA and functions in DNA replication, DNA repair, and checkpoint signaling. An early response to replication stress is ATR activation, which occurs when RPA accumulates on ssDNA. Activated ATR phosphorylates many targets, including the RPA32 subunit of RPA, leading to Chk1 activation and replication arrest. DNA-PK also phosphorylates RPA32 in response to replication stress, and we demonstrate that cells with DNA-PK defects, or lacking RPA32 Ser4/Ser8 targeted by DNA-PK, confer similar phenotypes, including defective replication checkpoint arrest, hyper-recombination, premature replication fork restart, failure to block late origin firing, and increased mitotic catastrophe. We present evidence that hyper-recombination in these mutants is ATM-dependent, but the other defects are ATM-independent. These results indicate that DNA-PK and ATR signaling through RPA32 plays a critical role in promoting genome stability and cell survival in response to replication stress.     

Methylation of MRE11 Regulates its Nuclear Compartmentalization

The cellular response to DNA damage includes the orderly recruitment of many proteincomplexes to DNA lesions. The MRE11-RAD50-NBS1 (MRN) complex is well knownto localize early to sites of DNA damage, but the post-translational modificationsrequired to mobilize it to DNA damage sites are poorly understood. Recently, we haveshown that MRE11 is arginine methylated in a C-terminal glycine-arginine rich (GAR)domain by protein arginine methyltransferase 1 (PRMT1). Arginine methylation isrequired for the exonuclease activity of MRE11 and the intra-S phase DNA damageresponse. Herein, we report that cells treated with methylase inhibitors failed to relocalizeMRE11 from PML nuclear bodies to sites of DNA damage and formed few ?-H2AX foci. We also demonstrate that PRMT1 is a component of PML nuclear bodieswhere it co-localizes with MRE11. Using cellular fractionation, we demonstrate thatmethylated MRE11 is predominantly associated with nuclear structures and that MRE11methylated arginines were required for this association. These results suggest thatMRE11 methylation regulates its association with nuclear structures such as PML nuclearbodies and sites of DNA damage.     

Closing the gaps among a web of DNA repair disorders

As recently as six years ago, three human diseases with similar phenotypes were mistakenly believed to be caused by a single genetic defect. The three diseases, Ataxia-telangiectasia, Nijmegen breakage syndrome, and an AT-like disorder are now known, however, to have defects in three separate genes: ATM, NBS1, and MRE11. Furthermore, new recent studies have shown now that all three gene products interact; the ATM kinase phosphorylates NBS1, which, in turn, associates with MRE11 to regulate DNA repair. Remarkably or expectedly, depending on one's point of view, the similarity in disease phenotypes is evidently due to defects in a common DNA repair pathway.     

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.     

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.     

DNA Damage Response as an Anti-Cancer Barrier: Damage Threshold and the Concept of 'Conditional Haploinsufficiency'

DNA damage response (DDR) emerges as a biological tumorigenesis barrier in early stages of cancer development, and a selective pressure that favors outgrowth of malignant clones with defects in the genome maintenance machinery, such as mutations of p53 and other DDR components. Recent studies indicate that the DDR barrier is not alarmed universally among early noninvasive lesions, but rather responds to high-risk tumorigenic threats that occur in high-grade, pre-malignant lesions that are generally more likely to develop into bona fide malignancies. In addition, while the DDR barrier appears to operate in major types of cancer, such as carcinomas of the lung, breast and colon, DDR activation is rare at any stage of progression among testicular germ-cell tumors. Together with observations that several, but not all oncogenic insults are capable of activating the DDR machinery, these new results point to existence of a critical threshold of such oncogene-induced DNA damage. It seems that only cells and lesions that experience DNA replication stress and DNA damage above such threshold activate the cellular senescence or cell death pathways within the DDR machinery. The higher load of DNA damage may also contribute to cancer predisposition in families with inherited heterozygous defects in the DDR barrier, such as in ATM, BRCA1, BRCA2, p53 and other genes. We propose that carriers of such DDR defects may be more prone to malignancy due to ‘conditional haploinsufficiency’: such partial defects may be asymptomatic in normal tissues, yet they may become manifest under conditions of supra-threshold endogenous DNA damage in oncogene-driven pre-malignant lesions.     

Werner Syndrome Protein and the MRE11 Complex are Involved in a Common Pathway of Replication Fork Recovery

Werner syndrome (WS) is an autosomal recessive disease that predisposes individuals toa wide range of cancers. The gene mutated in WS, WRN, encodes a member of the RecQfamily of DNA helicases. The precise DNA metabolic processes in which WRN participatesremain to be elucidated. However, it has been proposed that WRN might play an importantrole in the maintenance of genetic stability during DNA replication, possibly cooperatingwith other proteins. Here, we show that, following DNA replication arrest, WRN associatesand colocalises with the MRE11 complex at PCNA sites. We also provide evidence thatboth WRN/MRE11 complex association and proper WRN relocalisation after HU treatmentrequire a functional MRE11 complex. We demonstrate that mutations altering thefunctionality of WRN or that of the MRE11 complex result in chromosomal breakage duringDNA replication and enhanced cell death following replication arrest. Finally, we show thatthe DNA breakage in replicating cells and apoptosis observed in WS are not enhanced byconcomitant knock down of MRE11 by RNAi, indicating that WRN and MRE11 complexact in a common pathway. These results suggest a functional relationship between WRNand the MRE11 complex in response to replication fork arrest, disclosing a common actionof WRN and the MRE11 complex in the pathway(s) preserving genome stability duringDNA replication.     

The complexity of phosphorylated H2AX foci formation and DNA repair assembly at DNA double-strand breaks

The maintenance of genome stability requires efficient DNA double-stranded break (DSB) repair mediated by the phosphorylation of multiple histone H2AX molecules near the break sites. The phosphorylated H2AX (γ-H2AX) molecules form foci covering many megabases of chromatin. The formation of g-H2AX foci is critical for efficient DNA damage response (DDR) and for the maintenance of genome stability, however, the mechanisms of protein organization in foci is largely unknown. To investigate the nature of γ-H2AX foci formation, we analyzed the distribution of γ-H2AX and other DDR proteins at DSB sites using a variety of techniques to visualize, expand and partially disrupt chromatin. We report here that γ-H2AX foci change composition during the cell cycle, with proteins 53BP1, NBS1 and MRE11 dissociating from foci in G2 and mitosis to return at the beginning of the following G1. In contrast, MDC1 remained colocalized with g-H2AX during mitosis. In addition, while γ-H2AX was found to span large domains flanking DSB sites, 53BP1 and NBS1 were more localized and MDC1 colocalized in doublets in foci. H2AX and MDC1 were found to be involved in chromatin relaxation after DSB formation. Our data demonstrates that the DSB repair focus is a heterogeneous and dynamic structure containing internal complexity.     

HP1 promotes tumor suppressor BRCA1 functions during the DNA damage response

The DNA damage response (DDR) involves both the control of DNA damage repair and signaling to cell cycle checkpoints. Therefore, unraveling the underlying mechanisms of the DDR is important for understanding tumor suppression and cellular resistance to clastogenic cancer therapeutics. Because the DDR is likely to be influenced by chromatin regulation at the sites of DNA damage, we investigated the role of heterochromatin protein 1 (HP1) during the DDR process. We monitored double-strand breaks (DSBs) using the γH2AX foci marker and found that depleting cells of HP1 caused genotoxic stress, a delay in the repair of DSBs and elevated levels of apoptosis after irradiation. Furthermore, we found that these defects in repair were associated with impaired BRCA1 function. Depleting HP1 reduced recruitment of BRCA1 to DSBs and caused defects in two BRCA1-mediated DDR events: (i) the homologous recombination repair pathway and (ii) the arrest of cell cycle at the G₂/M checkpoint. In contrast, depleting HP1 from cells did not affect the non-homologous end-joining (NHEJ) pathway: instead it elevated the recruitment of the 53BP1 NHEJ factor to DSBs. Notably, all three subtypes of HP1 seemed to be almost equally important for these DDR functions. We suggest that the dynamic interaction of HP1 with chromatin and other DDR factors could determine DNA repair choice and cell fate after DNA damage. We also suggest that compromising HP1 expression could promote tumorigenesis by impairing the function of the BRCA1 tumor suppressor.