Function In DNA Double-strand Break Repair Research Articles

PARylation of GCN5 by PARP1 mediates its recruitment to DSBs and facilitates both HR and NHEJ Repair

Efficient DNA double strand break (DSB) repair is necessary for genomic stability and determines efficacy of DNA damaging cancer therapeutics. Spatiotemporal dynamics and post-translational modifications of repair proteins at DSBs dictate repair efficacy. Here, we identified a non-canonical function of GCN5 in regulating both HR and NHEJ repair post genotoxic stress. Mechanistically, genotoxic stress induced GCN5 recruitment to DSBs. GCN5 PARylation by PARP1 was essential for its recruitment, acetyltransferase activity and DSB repair function. Liquid chromatography-mass spectrometry (LC–MS) identified DNA-PKcs as part of GCN5 interactome. In-vitro acetyltransferase assays revealed that GCN5 acetylates DNA-PKcs at K3241 residue, a prerequisite for DNA-PKcs S2056 phosphorylation and DSB recruitment. Alongside, ChIP-qPCR revealed GCN5 mediates transcription of PRKDC via H3K27Ac acetylation in its promoter region (− 710 to − 554). Genetic perturbation of GCN5 also decreased CHEK1, NBN1, TP53BP1, POL-L transcription and abrogated ATM, BRCA1 activation. Accordingly, GCN5 loss led to persistent ɣ-H2AX foci formation, compromised in-vivo HR-NHEJ and caused GBM radio-sensitization. Importantly, PARP1 inhibition phenocopied GCN5 loss. Together, this study identifies an untraversed DSB repair function of GCN5 and provides mechanistic insights into transcriptional as well as post-translational regulation of pivotal HR-NHEJ factors. Alongside, it highlights the translational importance of PARP1-GCN5 axis in mediating GBM radio-resistance.

Abstract 1720: 53BP1 regulates heterochromatin through liquid-liquid phase separation (LLPS)

Abstract As compacted DNA, heterochromatin represses abnormal gene expression by inhibiting DNA transcription and maintains genome integrity by protecting aberrant chromosome segregation. Therefore, abnormalities in heterochromatin function are commonly found in cancer. However, how exactly heterochromatin preserves the genome integrity remains poorly understood due largely to the complex structure of heterochromatin. Recently, increasing evidence suggests that heterochromatin factors, including HP1α, KAP1, and SUV39H1/2, could drive the soluble heterochromatin into phase-separated droplets/condensates to promote gene silencing, which is referred to as liquid-liquid phase separation (LLPS). TP53-binding protein 1 (53BP1) has traditionally been a critical factor in DNA double-strand break (DSB) repair. We recently reported an unexpected finding that under normal growth conditions, 53BP1 regulates heterochromatin function through LLPS, which is independent of its DSB repair function. Our studies reveal a new paradigm in studying 53BP1, heterochromatin, and genome stability. However, an important question remains unanswered: how 53BP1 is recruited to heterochromatin to undergo LLPS and the associated broad biological impact. To address this question, we performed a special crosslinking coupled mass spectrometry to uncover potential factors in the 53BP1 condensates assembled on heterochromatin. We identified many factors associated with DNA methylation and histone modification, which are the two main steps in restoring heterochromatin epigenetic modification. Their interactions with 53BP1 at heterochromatin were confirmed by different approaches. We further focused on one of the key factors, PCNA, and carried out a detailed analysis of the interaction between PCNA and 53BP1 and the role of such interaction in 53BP1 LLPS, DSB repair, and heterochromatin function. These findings reveal the previously uncharacterized function of 53BP1 at heterochromatin during normal DNA replication. Citation Format: Xinran Geng, Youwei Zhang. 53BP1 regulates heterochromatin through liquid-liquid phase separation (LLPS) [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2024; Part 1 (Regular Abstracts); 2024 Apr 5-10; San Diego, CA. Philadelphia (PA): AACR; Cancer Res 2024;84(6_Suppl):Abstract nr 1720.

Nemo-Dependent, ATM-Mediated Signals from RAG DNA Breaks at Igk Feedback Inhibit V κ Recombination to Enforce Igκ Allelic Exclusion.

Monoallelic AgR gene expression underlies specific adaptive immune responses. AgR allelic exclusion is achieved by sequential initiation of V(D)J recombination between alleles and resultant protein from one allele signaling to prevent recombination of the other. The ATM kinase, a regulator of the DNA double-strand break (DSB) response, helps enforce allelic exclusion through undetermined mechanisms. ATM promotes repair of RAG1/RAG2 (RAG) endonuclease-induced DSBs and transduces signals from RAG DSBs during Igk gene rearrangement on one allele to transiently inhibit RAG1 protein expression, Igk accessibility, and RAG cleavage of the other allele. Yet, the relative contributions of ATM functions in DSB repair versus signaling to enforce AgR allelic exclusion remain undetermined. In this study, we demonstrate that inactivation in mouse pre-B cells of the NF-κB essential modulator (Nemo) protein, an effector of ATM signaling, diminishes RAG DSB-triggered repression of Rag1/Rag2 transcription and Igk accessibility but does not result in aberrant repair of RAG DSBs like ATM inactivation. We show that Nemo deficiency increases simultaneous biallelic Igk cleavage in pre-B cells and raises the frequency of B cells expressing Igκ proteins from both alleles. In contrast, the incidence of biallelic Igκ expression is not elevated by inactivation of the SpiC transcriptional repressor, which is induced by RAG DSBs in an ATM-dependent manner and suppresses Igk accessibility. Thus, we conclude that Nemo-dependent, ATM-mediated DNA damage signals enforce Igκ allelic exclusion by orchestrating transient repression of RAG expression and feedback inhibition of additional Igk rearrangements in response to RAG cleavage on one Igk allele.

Structural basis for the coiled-coil architecture of human CtIP

The DNA repair factor CtIP has a critical function in double-strand break (DSB) repair by homologous recombination, promoting the assembly of the repair apparatus at DNA ends and participating in DNA-end resection. However, the molecular mechanisms of CtIP function in DSB repair remain unclear. Here, we present an atomic model for the three-dimensional architecture of human CtIP, derived from a multi-disciplinary approach that includes X-ray crystallography, small-angle X-ray scattering (SAXS) and diffracted X-ray tracking (DXT). Our data show that CtIP adopts an extended dimer-of-dimers structure, in agreement with a role in bridging distant sites on chromosomal DNA during the recombinational repair. The zinc-binding motif in the CtIP N-terminus alters dynamically the coiled-coil structure, with functional implications for the long-range interactions of CtIP with DNA. Our results provide a structural basis for the three-dimensional arrangement of chains in the CtIP tetramer, a key aspect of CtIP function in DNA DSB repair.

Functional analysis of XRCC4 mutations in reported microcephaly and growth defect patients in terms of radiosensitivity.

Non-homologous end joining is one of the main pathways for DNA double-strand break (DSB) repair and is also implicated in V(D)J recombination in immune system. Therefore, mutations in non-homologous end-joining (NHEJ) proteins were found to be associated with immunodeficiency in human as well as in model animals. Several human patients with mutations in XRCC4 were reported to exhibit microcephaly and growth defects, but unexpectedly showed normal immune function. Here, to evaluate the functionality of these disease-associated mutations of XRCC4 in terms of radiosensitivity, we generated stable transfectants expressing these mutants in XRCC4-deficient murine M10 cells and measured their radiosensitivity by colony formation assay. V83_S105del, R225X and D254Mfs*68 were expressed at a similar level to wild-type XRCC4, while W43R, R161Q and R275X were expressed at even higher level than wild-type XRCC4. The expression levels of DNA ligase IV in the transfectants with these mutants were comparable to that in the wild-type XRCC4 transfectant. The V83S_S105del transfectant and, to a lesser extent, D254Mfs*68 transfectant, showed substantially increased radiosensitivity compared to the wild-type XRCC4 transfectant. The W43R, R161Q, R225X and R275X transfectants showed a slight but statistically significant increase in radiosensitivity compared to the wild-type XRCC4 transfectant. When expressed as fusion proteins with Green fluorescent protein (GFP), R225X, R275X and D254Mfs*68 localized to the cytoplasm, whereas other mutants localized to the nucleus. These results collectively indicated that the defects of XRCC4 in patients might be mainly due to insufficiency in protein quantity and impaired functionality, underscoring the importance of XRCC4’s DSB repair function in normal development.

RNF8 ubiquitinates RecQL4 and promotes its dissociation from DNA double strand breaks

Ubiquitination-dependent DNA damage response (DDR) signals play a critical role in the cellular choice of DNA damage repair pathways. Human DNA helicase RecQL4 participates in DNA replication and repair, and loss of RecQL4 is associated with autosomal recessive genetic disorders characterized by genomic instability features. In an earlier study, RecQL4 was isolated as a stable complex that contained two ubiquitin ligases of the N-end rule (UBR1 and UBR2). However, it is unknown whether or not RecQL4 ubiquitination status is critical for its DNA repair function. Here, we report that RecQL4 directly interacts with RNF8 (a RING finger ubiquitin E3 ligase), and both co-localize at DNA double-strand break (DSB) sites. Our findings indicate that RNF8 ubiquitinates RecQL4 protein mainly at the lysine sites of 876, 1048, and 1101, thereby facilitating the dissociation of RecQL4 from DSB sites. RecQL4 mutant at ubiquitination sites had a significantly prolonged retention at DSBs, which hinders the recruitment of its direct downstream DSB repair proteins (CtIP & Ku80). Interestingly, reduced DSB repair capacity observed in RecQL4 depleted cells was restored only by the reconstitution of wild-type RecQL4, but not the ubiquitination mutant. Additionally, RecQL4 directly interacts with WRAP53β that is known to recruit RNF8 to DSBs and WRAP53β enhances the association of RecQL4 with RNF8. WRAP53β silencing resulted in a nearly diminished recruitment of RNF8 to DSBs and in a greatly attenuated dissociation of RecQL4 from the DSB sites. Collectively, our study demonstrates that the ubiquitination event mediated by RNF8 constitutes an essential component for RecQL4’s function in DSB repair.

COMMD1, from the Repair of DNA Double Strand Breaks, to a Novel Anti-Cancer Therapeutic Target.

Simple SummaryLung cancer is the most commonly diagnosed cancer worldwide and additionally the most common cause of death from cancer, with non-small cell lung cancers (NSCLC) being the most commonly diagnosed form of the disease. As drug resistance is a key issue halting chemotherapy effectiveness, there is a great need to identify new therapeutic targets. The aims of this study were to investigate the function of the protein, COMMD1, in the repair of DNA double strand breaks and the therapeutic potential of COMMD1 in NSCLC. Here, we demonstrate for the first time how an additional COMMD family member, COMMD1, functions in the repair of DNA double strand breaks and may be relevant as a therapeutic target and prognostic factor in NSCLC. These novel findings highlight the potential of a novel approach to NSCLC therapy, by targeting an overexpressed protein. Lung cancer has the highest incidence and mortality among all cancers, with non-small cell lung cancer (NSCLC) accounting for 85–90% of all lung cancers. Here we investigated the function of COMMD1 in the repair of DNA double strand breaks (DSBs) and as a prognostic and therapeutic target in NSCLC. COMMD1 function in DSB repair was investigated using reporter assays in COMMD1-siRNA-depleted cells. The role of COMMD1 in NSCLC was investigated using bioinformatic analysis, qRT-PCR and immunoblotting of control and NSCLC cells, tissue microarrays, cell viability and cell cycle experiments. DNA repair assays demonstrated that COMMD1 is required for the efficient repair of DSBs and reporter assays showed that COMMD1 functions in both non-homologous-end-joining and homologous recombination. Bioinformatic analysis showed that COMMD1 is upregulated in NSCLC, with high levels of COMMD1 associated with poor patient prognosis. COMMD1 mRNA and protein were upregulated across a panel of NSCLC cell lines and siRNA-mediated depletion of COMMD1 decreased cell proliferation and reduced cell viability of NSCLC, with enhanced death after exposure to DNA damaging-agents. Bioinformatic analyses demonstrated that COMMD1 levels positively correlate with the gene ontology DNA repair gene set enrichment signature in NSCLC. Taken together, COMMD1 functions in DSB repair, is a prognostic maker in NSCLC and is potentially a novel anti-cancer therapeutic target for NSCLC.

BRCA-related ATM-mediated DNA double-strand break repair and ovarian aging.

Oocyte aging has significant clinical consequences, and yet no treatment exists to address the age-related decline in oocyte quality. The lack of progress in the treatment of oocyte aging is due to the fact that the underlying molecular mechanisms are not sufficiently understood. BRCA1 and 2 are involved in homologous DNA recombination and play essential roles in ataxia telangiectasia mutated (ATM)-mediated DNA double-strand break (DSB) repair. A growing body of laboratory, translational and clinical evidence has emerged within the past decade indicating a role for BRCA function and ATM-mediated DNA DSB repair in ovarian aging. Although there are several competing or complementary theories, given the growing evidence tying BRCA function and ATM-mediated DNA DSB repair mechanisms in general to ovarian aging, we performed this review encompassing basic, translational and clinical work to assess the current state of knowledge on the topic. A clear understanding of the mechanisms underlying oocyte aging may result in targeted treatments to preserve ovarian reserve and improve oocyte quality. We searched for published articles in the PubMed database containing key words, BRCA, BRCA1, BRCA2, Mutations, Fertility, Ovarian Reserve, Infertility, Mechanisms of Ovarian Aging, Oocyte or Oocyte DNA Repair, in the English-language literature until May 2019. We did not include abstracts or conference proceedings, with the exception of our own. Laboratory studies provided robust and reproducible evidence that BRCA1 function and ATM-mediated DNA DSB repair, in general, weakens with age in oocytes of multiple species including human. In both women with BRCA mutations and BRCA-mutant mice, primordial follicle numbers are reduced and there is accelerated accumulation of DNA DSBs in oocytes. In general, women with BRCA1 mutations have lower ovarian reserves and experience earlier menopause. Laboratory evidence also supports critical role for BRCA1 and other ATM-mediated DNA DSB repair pathway members in meiotic function. When laboratory, translational and clinical evidence is considered together, BRCA-related ATM-mediated DNA DSB repair function emerges as a likely regulator of ovarian aging. Moreover, DNA damage and repair appear to be key features in chemotherapy-induced ovarian aging. The existing data suggest that the BRCA-related ATM-mediated DNA repair pathway is a strong candidate to be a regulator of oocyte aging, and the age-related decline of this pathway likely impairs oocyte health. This knowledge may create an opportunity to develop targeted treatments to reverse or prevent physiological or chemotherapy-induced oocyte aging. On the immediate practical side, women with BRCA or similar mutations may need to be specially counselled for fertility preservation.

XRN2 Depletion is Synthetic Lethal with PARP1 Inhibition

Persistent R‐loops (RNA‐DNA hybrids with a displaced single‐stranded DNA) create DNA damage and lead to genomic instability. The 5’‐3’‐exoribonuclease 2 (XRN2) degrades RNA to resolve R‐loops and promotes transcription termination. Previously, XRN2 was implicated in DNA double strand break (DSB) repair and in resolving replication stress. XRN2 function in DSB repair is not fully understood. We hypothesize that XRN2 plays a critical role in multiple DNA repair pathways. Here, using tandem affinity purification‐mass spectrometry, bioinformatics, and biochemical approaches, we found that XRN2 associates with proteins involved in DNA repair/replication (Ku70‐Ku80, DNA‐PKcs, PARP1, MCM2‐7, PCNA, RPA1), and RNA metabolism (RNA helicases, PRP19, p54(nrb), splicing factors). Novel major pathways linked to XRN2 include cell cycle control of chromosomal replication and DSB repair by non‐homologous end joining. Investigating the biological implications of these interactions led us to discover that XRN2 depletion compromised cell survival after additional knockdown of specific DNA repair proteins, including PARP1. XRN2‐deficient cells also showed enhanced PARP1 activity. Consistent with concurrent depletion of XRN2 and PARP1 promoting cell death, XRN2‐deficient fibroblast and lung cancer cells also demonstrated sensitivity to PARP1 inhibition. The XRN2 alterations (mutations, copy number/expression changes) are frequent in cancers. Thus, PARP1 inhibition could target cancers exhibiting XRN2 functional loss. Collectively, our data suggest XRN2's association with novel protein partners and unravel synthetic lethality between XRN2 loss and PARP1 inhibition.Support or Funding InformationThis work was largely supported by the National Institutes of Health/National Cancer Institute (NCI/NIH) [R01 CA139217] to D.A.B, a minority supplement [R01 CA139217‐05S1] and the Cancer Biology Training Grant T32CA124334‐06 to E.A.M. (PI: Dr. Jerry Shay), Simmons Comprehensive Cancer Center, UT Southwestern. This work was also supported by grant 5P30CA142543, NCI/NIH to the UT Southwestern Proteomics Core. The UT Southwestern Proteomics Core was also supported, in part, by a grant from the Cancer Prevention and Research Institute of Texas [CPRIT, RP1206130] to Dr. Hamid Mirzaei. Funding for open access charges was from NCI/NIH CA139217 to D.A.B. Research reported in this study was also supported by the UT Southwestern CCSG grant 5P30CA142543 from the NCI/NIH.This abstract is from the Experimental Biology 2019 Meeting. There is no full text article associated with this abstract published in The FASEB Journal.

Abstract P3-11-06: HRD (homologous recombination deficiency) score and its clinicopathological features in neoadjuvant chemotherapy treated sporadic breast cancers

Abstract [Purpose]Homologous Recombination Deficiency (HRD) score has been developed to evaluate the DNA double-strand break repair function. BRCA1/2 germline mutation-associated breast cancers are known to show a high HRD score and a high sensitivity to platinum-based chemotherapy as well as PARP inhibitor. HRD can be theoretically induced by not only the dysfunction of BRA1/2 but also the dysfunction of the other molecules involved in homologous recombination, and, actually, high HRD score is reported to be seen in a significant proportion of sporadic breast tumors without BRCA1/2 mutation. The aim of the present study was to elucidate the clinicopathological characteristics of sporadic breast tumors with high HRD score as well as their sensitivity to sequential paclitaxel and FEC chemotherapy (P-FEC). [Methods]Tumor tissues obtained by Mammotome from 132 sporadic breast cancer patients (stage II-III) before neoadjuvant chemotherapy with P-FEC were subjected to assay for HRD score using Oncoscan CNV kit®. HRD score was a simple sum of NtAI, LOH, and LST (cutoff, 42), and were also subjected to the gene expression analysis using the Affymetrix microarray (U133 plus 2.0). BRCA1 promoter methylation was assayed by methylation specific real-time PCR. [Result]Of the 132 breast tumors, 32% showed a high HRD score which were significantly associated with high histological grade (P=0.001), negative progesterone receptor (P=0.023) and high Ki67 index (P=0.004). Triple negative breast cancer (TNBC)(n=19) showed a significantly (P<0.001) higher HRD score than the other subtypes (HR+/HER2-(n=73), HR+/HER2+(n=12), HR-/HER2+(n=18)). BRCA1 promoter methylation was significantly associated with a high HRD score. There was no significant correlation between HRD score and pCR to P-FEC when all tumors were considered but tumors with a high HRD score showed a significantly (P=0.020) lower pCR rate when only TNBC were considered. In TNBC, majority of tumors showed a high HRD score in five subtypes (BL1, BL2, IM, M, MSL) but no tumor showed a high HRD score in LAR (luminal androgen receptor) subtype. [Conclusion]Approximately one third of sporadic breast tumors show a high HRD score, indicating the presence of homologous recombination dysfunction, and they are most often seen in TNBC with BRCA1 promoter methylation and never in LAR subtype. Interestingly, breast tumors with a high HRD score were less sensitive to P-FEC. Citation Format: Imanishi S, Naoi Y, Shimazu K, Shimoda M, Kagara N, Tanei T, Miyake T, Kim SJ, Noguchi S. HRD (homologous recombination deficiency) score and its clinicopathological features in neoadjuvant chemotherapy treated sporadic breast cancers [abstract]. In: Proceedings of the 2018 San Antonio Breast Cancer Symposium; 2018 Dec 4-8; San Antonio, TX. Philadelphia (PA): AACR; Cancer Res 2019;79(4 Suppl):Abstract nr P3-11-06.

A Commentary on TDP-43 and DNA Damage Response in Amyotrophic Lateral Sclerosis.

Amyotrophic lateral sclerosis (ALS) is a devastating, motor neuron degenerative disease without any cure. About 95% of the ALS patients feature abnormalities in the RNA/DNA-binding protein, TDP-43, involving its nucleo-cytoplasmic mislocalization in spinal motor neurons. How TDP-43 pathology triggers neuronal apoptosis remains unclear. In a recent study, we reported for the first time that TDP-43 participates in the DNA damage response (DDR) in neurons, and its nuclear clearance in spinal motor neurons caused DNA double-strand break (DSB) repair defects in ALS. We documented that TDP-43 was a key component of the non-homologous end joining (NHEJ) pathway of DSB repair, which is likely the major pathway for repair of DSBs in post-mitotic neurons. We have also uncovered molecular insights into the role of TDP-43 in DSB repair and showed that TDP-43 acts as a scaffold in recruiting the XRCC4/DNA Ligase 4 complex at DSB damage sites and thus regulates a critical rate-limiting function in DSB repair. Significant DSB accumulation in the genomes of TDP-43-depleted, human neural stem cell-derived motor neurons as well as in ALS patient spinal cords with TDP-43 pathology, strongly supported a TDP-43 involvement in genome maintenance and toxicity-induced genome repair defects in ALS. In this commentary, we highlight our findings that have uncovered a link between TDP-43 pathology and impaired DNA repair and suggest potential possibilities for DNA repair-targeted therapies for TDP-43-ALS.

Abstract IA27: Exploiting the inhibition of cullin-RING-ligases in DSB repair as a therapeutic strategy

Abstract While single component E3 ubiquitin ligases have established roles in DNA double-strand break (DSB) repair, the function of multicomponent cullin-RING-ligases (CRL) in DSB repair is only beginning to emerge. FBXW7 is a substrate recognition component of Skp1-Cullin1-F-box E3 ubiquitin ligases previously known only to regulate the proteasomal degradation of substrates such as Cyclin E and MCL1. Given that FBXW7 loss promotes genomic instability, we hypothesized that FBXW7 may have a direct function in DSB repair. To establish the functions of FBXW7 in DSB repair, we first demonstrated the rapid localization of FBXW7 to DSB sites in an ATM-dependent manner. Subsequently, we found that FBXW7 depletion impaired nonhomologous end-joining (NHEJ), but not homologous recombination (HR) repair, resulting in persistent radiation-induced DSBs. Investigation of the molecular mechanisms of FBXW7 in NHEJ revealed that FBXW7 interacts with and promotes K63-linked ubiquitination of XRCC4. This ubiquitination of XRCC4 promotes interaction between the XRCC4/XLF/LIG4 and DNAPK/KU70/KU80 complexes to facilitate NHEJ. To begin to therapeutically leverage this mechanism, strategies to both pharmacologically inhibit FBXW7-CRLs and to exploit FBXW7 mutations occurring in human cancers are being developed. To address the former, pevonedistat (MLN4924), an agent which inhibits CRLs via inhibition of cullin-neddylation, inhibits FBXW7-mediated XRCC4 ubiquitination and NHEJ. This activity leads to increased sensitivity of tumor cells to chemotherapy and radiation and represents a strategy that may be particularly effective in cancers with other DSB repair defects. As another strategy to leverage the mechanisms of FBXW7 in NHEJ, loss-of-function mutations in the WD domain of FBXW7 which occur frequently in human cancers are being explored. These mutations render cells defective in NHEJ and more sensitive to DNA damage. Thus, we hypothesize that inhibition of other DSB repair pathways (e.g. alternative-end-joining) may be an effective therapeutic strategy for FBXW7 mutant cancers. These novel mechanisms of NHEJ regulation as well as their implications in the treatment of human cancers with an emphasis on pancreatic and colorectal cancers will be discussed. This work was supported by NIH grants R01CA163895, P50CA130810, R01CA118762, R01CA156744, and R01CA171277. Citation Format: Meredith Morgan. Exploiting the inhibition of cullin-RING-ligases in DSB repair as a therapeutic strategy [abstract]. In: Proceedings of the AACR Special Conference on DNA Repair: Tumor Development and Therapeutic Response; 2016 Nov 2-5; Montreal, QC, Canada. Philadelphia (PA): AACR; Mol Cancer Res 2017;15(4_Suppl):Abstract nr IA27.

Lysine 271 but not lysine 210 of XRCC4 is required for the nuclear localization of XRCC4 and DNA ligase IV

XRCC4 and DNA Ligase IV (LIG4) cooperate to join two DNA ends at the final step of DNA double-strand break (DSB) repair through non-homologous end-joining (NHEJ). However, it is not fully understood how these proteins are localized to the nucleus. Here we created XRCC4K271R mutant, as Lys271 lies within the putative nuclear localization signal (NLS), and XRCC4K210R mutant, as Lys210 was reported to undergo SUMOylation, implicated in the nuclear localization of XRCC4. Wild-type and mutated XRCC4 with EGFP tag were introduced into HeLa cell, in which endogenous XRCC4 had been knocked down using siRNA directed to 3′-untranslated region, and tested for the nuclear localization function by fluorescence microscopy. XRCC4K271R was defective in the nuclear localization of itself and LIG4, whereas XRCC4K210R was competent for the nuclear localization with LIG4. To examine DSB repair function, wild-type and mutated XRCC4 were introduced into XRCC4-deficient M10. M10-XRCC4K271R, but not M10-XRCC4K210R, showed significantly reduced surviving fraction after 2 Gy γ-ray irradiation as compared to M10-XRCC4WT. The number of γ-H2AX foci remaining 2 h after 2 Gy γ-ray irradiation was significantly greater in M10-XRCC4K271R than in M10-XRCC4WT, whereas it was only marginally increased in M10-XRCC4K210R as compared to M10-XRCC4WT. The present results collectively indicated that Lys271, but not Lys210, of XRCC4 is required for the nuclear localization of XRCC4 and LIG4 and that the nuclear localizing ability is essential for DSB repair function of XRCC4.

New Insights into the Post-Translational Regulation of DNA Damage Response and Double-Strand Break Repair in Caenorhabditis elegans.

Although a growing number of studies have reported the importance of SUMOylation in genome maintenance and DNA double-strand break repair (DSBR), relevant target proteins and how this modification regulates their functions are yet to be clarified. Here, we analyzed SUMOylation of ZTF-8, the homolog of mammalian RHINO, to test the functional significance of this protein modification in the DSBR and DNA damage response (DDR) pathways in the Caenorhabditis elegans germline. We found that ZTF-8 is a direct target for SUMOylation in vivo and that its modification is required for DNA damage checkpoint induced apoptosis and DSBR. Non-SUMOylatable mutants of ZTF-8 mimic the phenotypes observed in ztf-8 null mutants, including reduced fertility, impaired DNA damage repair, and defective DNA damage checkpoint activation. However, while mutants for components acting in the SUMOylation pathway fail to properly localize ZTF-8, its localization is not altered in the ZTF-8 non-SUMOylatable mutants. Taken together, these data show that direct SUMOylation of ZTF-8 is required for its function in DSBR as well as DDR but not its localization. ZTF-8's human ortholog is enriched in the germline, but its meiotic role as well as its post-translational modification has never been explored. Therefore, our discovery may assist in understanding the regulatory mechanism of this protein in DSBR and DDR in the germline.

Asparagine 326 in the extremely C-terminal region of XRCC4 is essential for the cell survival after irradiation

XRCC4 is one of the crucial proteins in the repair of DNA double-strand break (DSB) through non-homologous end-joining (NHEJ). As XRCC4 consists of 336 amino acids, N-terminal 200 amino acids include domains for dimerization and for association with DNA ligase IV and XLF and shown to be essential for XRCC4 function in DSB repair and V(D)J recombination. On the other hand, the role of the remaining C-terminal region of XRCC4 is not well understood. In the present study, we noticed that a stretch of ∼20 amino acids located at the extreme C-terminus of XRCC4 is highly conserved among vertebrate species. To explore its possible importance, series of mutants in this region were constructed and assessed for the functionality in terms of ability to rescue radiosensitivity of M10 cells lacking XRCC4. Among 13 mutants, M10 transfectant with N326L mutant (M10-XRCC4N326L) showed elevated radiosensitivity. N326L protein showed defective nuclear localization. N326L sequence matched the consensus sequence of nuclear export signal. Leptomycin B treatment accumulated XRCC4N326L in the nucleus but only partially rescued radiosensitivity of M10-XRCC4N326L. These results collectively indicated that the functional defects of XRCC4N326L might be partially, but not solely, due to its exclusion from nucleus by synthetic nuclear export signal. Further mutation of XRCC4 Asn326 to other amino acids, i.e., alanine, aspartic acid or glutamine did not affect the nuclear localization but still exhibited radiosensitivity. The present results indicated the importance of the extremely C-terminal region of XRCC4 and, especially, Asn326 therein.

The catalytic subunit of DNA-dependent protein kinase is required for cellular resistance to oxidative stress independent of DNA double-strand break repair

DNA-dependent protein kinase catalytic subunit (DNA-PKcs) and ataxia telangiectasia mutated (ATM) are the two major kinases involved in DNA double-strand break (DSB) repair, and are required for cellular resistance to ionizing radiation. Whereas ATM is the key upstream kinase for DSB signaling, DNA-PKcs is primarily involved in DSB repair through the nonhomologous end-joining (NHEJ) mechanism. In addition to DSB repair, ATM has been shown to be involved in the oxidative stress response and could be activated directly in vitro on hydrogen peroxide (H2O2) treatment. However, the role of DNA-PKcs in cellular response to oxidative stress is not clear. We hypothesize that DNA-PKcs may participate in the regulation of ATM activation in response to oxidative stress, and that this regulatory role is independent of its role in DNA double-strand break repair. Our findings reveal that H2O2 induces hyperactivation of ATM signaling in DNA-PKcs-deficient, but not Ligase 4-deficient cells, suggesting an NHEJ-independent role for DNA-PKcs. Furthermore, DNA-PKcs deficiency leads to the elevation of reactive oxygen species (ROS) production, and to a decrease in cellular survival against H2O2. For the first time, our results reveal that DNA-PKcs plays a noncanonical role in the cellular response to oxidative stress, which is independent from its role in NHEJ. In addition, DNA-PKcs is a critical regulator of the oxidative stress response and contributes to the maintenance of redox homeostasis. Our findings reveal that DNA-PKcs is required for cellular resistance to oxidative stress and suppression of ROS buildup independently of its function in DSB repair.

Suppression of DNA-dependent protein kinase sensitize cells to radiation without affecting DSB repair

Efficient and correct repair of DNA double-strand break (DSB) is critical for cell survival. Defects in the DNA repair may lead to cell death, genomic instability and development of cancer. The catalytic subunit of DNA-dependent protein kinase (DNA-PKcs) is an essential component of the non-homologous end joining (NHEJ) which is the major DSB repair pathway in mammalian cells. In the present study, by using siRNA against DNA-PKcs in four human cell lines, we examined how low levels of DNA-PKcs affected cellular response to ionizing radiation. Decrease of DNA-PKcs levels by 80–95%, induced by siRNA treatment, lead to extreme radiosensitivity, similar to that seen in cells completely lacking DNA-PKcs and low levels of DNA-PKcs promoted cell accumulation in G2/M phase after irradiation and blocked progression of mitosis. Surprisingly, low levels of DNA-PKcs did not affect the repair capacity and the removal of 53BP1 or γ-H2AX foci and rejoining of DSB appeared normal. This was in strong contrast to cells completely lacking DNA-PKcs and cells treated with the DNA-PKcs inhibitor NU7441, in which DSB repair were severely compromised. This suggests that there are different mechanisms by which loss of DNA-PKcs functions can sensitize cells to ionizing radiation. Further, foci of phosphorylated DNA-PKcs (T2609 and S2056) co-localized with DSB and this was independent of the amount of DNA-PKcs but foci of DNA-PKcs was only seen in siRNA-treated cells. Our study emphasizes on the critical role of DNA-PKcs for maintaining survival after radiation exposure which is uncoupled from its essential function in DSB repair. This could have implications for the development of therapeutic strategies aiming to radiosensitize tumors by affecting the DNA-PKcs function.

An RNA polymerase II-coupled function for histone H3K36 methylation in checkpoint activation and DSB repair.

Histone modifications are major determinants of DNA double-strand break (DSB) response and repair. Here we elucidate a DSB repair function for transcription-coupled Set2 methylation at H3 lysine 36 (H3K36me). Cells devoid of Set2/H3K36me are hypersensitive to DNA-damaging agents and site-specific DSBs, fail to properly activate the DNA-damage checkpoint, and show genetic interactions with DSB-sensing and repair machinery. Set2/H3K36me3 is enriched at DSBs, and loss of Set2 results in altered chromatin architecture and inappropriate resection during G1 near break sites. Surprisingly, Set2 and RNA polymerase II are programmed for destruction after DSBs in a temporal manner – resulting in H3K36me3 to H3K36me2 transition that may be linked to DSB repair. Finally, we show a requirement of Set2 in DSB repair in transcription units – thus underscoring the importance of transcription-dependent H3K36me in DSB repair.

A mediator methylation mystery: JMJD1C demethylates MDC1 to regulate DNA repair

Mediator of DNA-damage checkpoint 1 (MDMDC1) has a central role in repair of DNA double-strand breaks (DSBs) by both homologous recombination and nonhomologous end joining, and its function is regulated by post-translational phosphorylation, ubiquitylation and sumoylation. In this issue, a new study by Watanabe et al. reveals that methylation of MDMDC1 is also critical for its function in DSB repair and specifically affects repair through BRCA1-dependent homologous recombination.

Chromatin acetylation, β-amyloid precursor protein and its binding partner FE65 in DNA double strand break repair.

Among post-translational modifications of chromatin proteins taking place in DNA double strand break (DSB) repair, acetylation plays a prominent role. This review lists several facts and hypotheses concerning this process. Lack of acetyltransferase TIP60 (HIV-Tat interacting protein of 60 kDa) activity results in cells with defective DSB repair. The enzyme is present in the nucleus in a multimeric protein complex. TIP60 dependent activation of ATM (ataxia telangiectasia mutated kinase) is an early event in the response to DNA breakage. Other important acetylations are those of histones H4 and γH2AX. Correct reconstruction of the damaged site is critical for survival and prevention of genetic and epigenetic changes in the cell that may affect the function of its daughter cells. Recently, two proteins with previously unsuspected functions in DSB repair have been identified as active in this process: Alzheimer β-amyloid precursor protein (APP) and its binding partner FE65, β-amyloid precursor binding protein. Their participation in DSB repair in both neuronal and non-neuronal cells is related to acetylation carried out by the acetyltransferase complex. The same function is ascribed to heterochromatin protein 1 (HP1). So far, the relations (if any) between TIP60 activation by HP1 and by the FE65 complex remain unidentified.