Description: Publication date: Available online 5 July 2018 Source: DNA Repair Author(s): Xiaoliang Chen, Xiaochun Zou, Weiyi Zhong, Ke Peng, Dongli Wang, Wei Fan, Jinbo Lin, Ji Peng Vast number of somatic mutations has been proved to be affected by the factors of sequencing methods, analysis pipelines and validation methods. We here showed the effect of autologous reference types on the detection of cancer-associated somatic mutations with the somatic single nucleotide variations (SNVs) and clinical data of solid tumors from the Cancer Genome Atlas (TCGA) and International Cancer Genome Consortium (ICGC). The distribution of somatic SNVs was significantly different among groups of autologous references in 6 cancers detected by whole genome sequencing (WGS) and 5 cancers detected by the random sequencing of exonic regions selected from the genome (WXS), especially in protein coding region of 5 cancers with age, gender and TNM adjusted. In addition, only 60.24% (95% CI: 49.65% – 70.83%) of the somatic SNVs called from normal blood by WXS were found in those called from normal solid tissue tested by WXS / WGS, while 31.78% (95%CI: 4.14% – 59.42%) of the somatic SNVs called from normal tissue adjacent to primary by WXS were found in those from normal blood tested by WXS / WGS. These findings suggested that more representative types of normal tissues should be included in detection of cancer-associated somatic mutations.

Description: Publication date: Available online 5 July 2018 Source: DNA Repair Author(s): Xiao-Nan Zhao, Karen Usdin The Fragile X-related disorders (FXDs) are members of a large group of human neurological or neurodevelopmental conditions known as the Repeat Expansion Diseases. The mutation responsible for all of these diseases is an expansion in the size of a disease-specific tandem repeat tract. However, the underlying cause of this unusual mutation is unknown. Genome-wide association studies have identified single nucleotide polymorphisms (SNPs) in the vicinity of the FAN1 (MIM 613534) gene that are associated with variations in the age at onset of a number of Repeat Expansion Diseases. FAN1 is a nuclease that has both 5’-3’ exonuclease and 5’ flap endonuclease activities. Here we show in a model for the FXDs that Fan1 -/- mice have expansions that, in some tissues including brain, are 2-3 times as extensive as they are in Fan1 +/+ mice. However, no effect of the loss of FAN1 was apparent for germ line expansions. Thus, FAN1 plays an important role in protecting against somatic expansions but is either not involved in protecting against intergenerational repeat expansions or is redundant with other related enzymes. However, since loss of FAN1 results in increased expansions in brain and other somatic tissue, FAN1 polymorphisms may be important disease modifiers in those Repeat Expansion Diseases in which somatic expansion contributes to age at onset or disease severity.

Description: Publication date: Available online 30 June 2018 Source: DNA Repair Author(s): Diego Dibitetto, Mattia La Monica, Matteo Ferrari, Federica Marini, Achille Pellicioli Cas9 endonuclease from S. pyogenes is widely used to induce controlled double strand breaks (DSB) at desired genomic loci for gene editing. Here, we describe a droplet digital PCR (ddPCR) method to precisely quantify the kinetic of formation and 5′-end nucleolytic processing of Cas9-induced DSB in different human cells lines. Notably, DSB processing is a finely regulated process, which dictates the choice between non-homologous end joining (NHEJ) and homology directed repair (HDR). This step of DSB repair is also a relevant point to be taken into consideration to improve Cas9-mediated technology. Indeed, by this protocol, we show that processing of Cas9-induced DSB is impaired by CTIP or BRCA1 depletion, while it is accelerated after down-regulation of DNA-PKcs and 53BP1, two DSB repair key factors. In conclusion, the method we describe here can be used to study DSB repair mechanisms, with direct utility for molecularly optimising the knock-out/in outcomes in genome manipulation. Graphical abstract

Description: Publication date: August 2018 Source: DNA Repair, Volume 68 Author(s): Nicole L. Batenburg, Jian Qin, John R. Walker, Xu-Dong Zhu The ATP-dependent chromatin remodeler CSB is implicated in a variety of different DNA repair mechanisms, including transcription-coupled nucleotide excision repair (TC-NER), base excision repair and DNA double strand break (DSB) repair. However, how CSB is regulated in these various repair processes is not well understood. Here we report that the first 30 amino acids of CSB along with two phosphorylation events on S10 and S158, previously reported to be required for CSB function in homologous recombination (HR)-mediated repair, are dispensable for repairing UV-induced DNA damage, suggesting that the regulation of CSB in these two types of repair are carried out by distinct mechanisms. In addition, we show that although the central ATPase domain of CSB is engaged in interactions with both the N- and C-terminal regions, these interactions are disrupted following UV-induced DNA damage. The UV-induced disengagement of the C-terminal region of CSB from the ATPase domain requires two conserved amino acids W1486 and L1488, which are thought to contribute to the hydrophobic core formation of the winged helix domain (WHD) at its C-terminus. Failure to undergo UV-induced dissociation of the C-terminal region of CSB from the ATPase domain is associated with impairment in its UV-induced chromatin association, its UV-induced post-translational modification as well as cell survival. Collectively, these findings suggest that UV-induced dissociation of CSB domain interactions is a necessary step in repairing UV-induced DNA damage and that the WHD of CSB plays a key role in this dissociation.

Description: Publication date: Available online 18 June 2018 Source: DNA Repair Author(s): Arisa Nakazato, Kinumi Kajita, Masato Ooka, Remi Akagawa, Takuya Abe, Shunichi Takeda, Dana Branzei, Kouji Hirota Prolonged replication arrest on damaged templates is a cause of fork collapse, potentially resulting in genome instability. Arrested replication is rescued by translesion DNA synthesis (TLS) and homologous recombination (HR)-mediated template switching. SPARTAN, a ubiquitin-PCNA-interacting regulator, regulates TLS via mechanisms incompletely understood. Here we show that SPARTAN promotes diversification of the chicken DT40 immunoglobulin-variable λ gene by facilitating TLS-mediated hypermutation and template switch-mediated gene-conversion, both induced by replication blocks at abasic sites. SPARTAN -/- and SPARTAN -/- / Polη -/- / Polζ -/- cells showed defective and similar decrease in hypermutation rates, as well as alterations in the mutation spectra, with decreased dG-to-dC transversions and increased dG-to-dA transitions. Strikingly, SPARTAN -/- cells also showed reduced template switch-mediated gene-conversion at the immunoglobulin locus, while being proficient in HR-mediated double strand break repair, and sister chromatid recombination. Notably, SPARTAN’s ubiquitin-binding zinc-finger 4 domain, but not the PCNA interacting peptide domain or its DNA-binding domain, was specifically required for the promotion of immunoglobulin gene-conversion, while all these three domains were shown to contribute similarly to TLS. In all, our results suggest that SPARTAN mediates TLS in concert with the Polη-Polζ pathway and that it facilitates HR-mediated template switching at a subset of stalled replication forks, potentially by interacting with unknown ubiquitinated proteins.

Description: Publication date: Available online 12 June 2018 Source: DNA Repair Author(s): Eric A. Josephs, Piotr E. Marszalek DNA mismatch repair (MMR) pathways coordinate the excision and re-synthesis of newly-replicated DNA if a mismatched base-pair has been identified by protein MutS or MutS homologues (MSHs) after replication. DNA excision during MMR is initiated at single-strand breaks (SSBs) in vitro , and several redundant processes have been observed in reconstituted systems which either require a pre-formed SSB in the DNA and/or require a mismatch-activated nicking endonuclease to introduce a new SSB in order to initiate MMR. However, the conditions under which each of these processes may actually occur in living cells have remained obscured by the limitations of current MMR assays. Here we use a novel assay involving chemically-modified oligonucleotide probes to insert targeted DNA ‘mismatches’ directly into the genome of living bacteria to interrogate their replication-coupled repair processes quantitatively in a strand-, orientation-, and mismatched nucleotide-specific manner. This ‘semi-protected oligonucleotide recombination’ (SPORE) assay reveals direct evidence in Escherichia coli of an efficient endonuclease-independent MMR process on the lagging strand—a mechanism that has long-since been considered for lagging-strand repair but never directly shown until now. We find endonuclease-independent MMR is coordinated asymmetrically with respect to the replicating DNA—directed primarily from 3′- of the mismatch—and that repair coordinated from 3′- of the mismatch is in fact the primary mechanism of lagging-strand MMR. While further work is required to explore and identify the molecular requirements for this alternative endonuclease-independent MMR pathway, these findings made possible using the SPORE assay are the first direct report of this long-suspected mechanism in vivo .

Description: Publication date: Available online 12 June 2018 Source: DNA Repair Author(s): Youn-Jung Kang, Catherine T. Yan Classical non-homologous end-joining (cNHEJ) is the main pathway for the repair of DNA double strand breaks (DSBs) in mammalian cells. In the absence of c-NHEJ, an alternative end-joining (A-EJ) mechanism resolves DSBs. To date, no A-EJ specific factor has been identified. Instead, this mechanism appears to co-opt proteins involved in more than one DNA repair pathway. These include components of base-excision repair (PARP1/XRCC1/LIG3), interstrand cross-link repair (BRCA1/FANCD2), and DSB response/DNA end-resection (MRE11A/RAD50/RBBP8). To clarify the contribution of these factors to A-EJ, here we examined their expression and recruitment to DSBs in correlation with surrogates of cNHEJ (53BP1) and homologous recombination (RAD51) in cells deficient for the cNHEJ end-ligation component XRCC4. This revealed XRCC4-deficient cells exhibited marked increases in the stability of A-EJ transcripts that result in correspondingly elevated levels of associated proteins, in comparison to WT cells. RAD51 was also increased while 53BP1 was unaffected. Treatment with radiomimetic DSB-inducing drug doxorubicin did not influence these activities. However, FANCD2, BRCA1 and XRCC1 foci, prominently associated with 53BP1 foci and hence DSBs resolved by cNHEJ, were only detected in doxorubicin-treated XRCC4-deficient cells. Strikingly, treatment of XRCC4-deficient cells with the PARP-specific inhibitor Niraparib enhanced A-EJ, and substantially induced 53BP1 transcripts and the numbers of A-EJ-associated 53BP1 DNA damage foci. RAD51 was severely inhibited, and upstream cNHEJ (KU70/KU80/DNA-PKCs/ARTEMIS) transcripts were substantially induced. These latter results were recapitulated in BRCA1-deficient cells, which contrastingly did not affect 53BP1 or PARP1 status irrespective of doxorubicin or Niraparib treatment. Hence A-EJ is regulated transcriptionally, reduced by a higher turnover rate in cNHEJ-proficient cells and sustained but fine-tuned by PARP1 in XRCC4-deficient cells to promote DNA repair and survival. Upstream cNHEJ components are similarly transcriptionally down-modulated by PARP1 and BRCA1 in a manner inversely correlated with HR and mechanistically distinct from A-EJ respectively in cNHEJ-deficient and cNHEJ-proficient settings.

Description: Publication date: June–July 2018 Source: DNA Repair, Volumes 66–67

Description: Publication date: August 2018 Source: DNA Repair, Volume 68 Author(s): Sri Lakshmi Chalasani, Ajinkya S. Kawale, Konstantin Akopiants, Yaping Yu, Mesfin Fanta, Michael Weinfeld, Lawrence F. Povirk Polynucleotide kinase/phosphatase (PNKP) has been implicated in non-homologous end joining (NHEJ) of DNA double-strand breaks (DSBs). To assess the consequences of PNKP deficiency for NHEJ of 3′-phosphate-ended DSBs, PNKP-deficient derivatives of HCT116 and of HeLa cells were generated using CRISPR/CAS9. For both cell lines, PNKP deficiency conferred sensitivity to ionizing radiation as well as to neocarzinostatin (NCS), which specifically induces DSBs bearing protruding 3′-phosphate termini. Moreover, NCS-induced DSBs, detected as 53BP1 foci, were more persistent in PNKP −/− HCT116 cells compared to their wild-type (WT) counterparts. Surprisingly, PNKP-deficient whole-cell and nuclear extracts were biochemically competent in removing both protruding and recessed 3′-phosphates from synthetic DSB substrates, albeit much less efficiently than WT extracts, suggesting an alternative 3′-phosphatase. Measurements by ligation-mediated PCR showed that PNKP-deficient HeLa cells contained significantly more 3′-phosphate-terminated and fewer 3′-hydroxyl-terminated DSBs than parental cells 5–15 min after NCS treatment, but this difference disappeared by 1 h. These results suggest that, despite presence of an alternative 3′-phosphatase, loss of PNKP significantly sensitizes cells to 3′-phosphate-terminated DSBs, due to a 3′-dephosphorylation defect.

Description: Publication date: Available online 18 May 2018 Source: DNA Repair Author(s): Jyotirindra Maity, Biswadip Das, Vilhelm A. Bohr, Parimal Karmakar Impaired autophagy may be associated with normal and pathological aging. Here we explore a link between autophagy and domain function of Werner protein (WRNp). Werner (WRN) mutant cell lines AG11395, AG05229 and normal aged fibroblast AG13129 display a deficient response to tunicamycin mediated endoplasmic reticulum (ER) stress induced autophagy compared to clinically unaffected GM00637 and normal young fibroblast GM03440. Cellular endoplasmic reticulum (ER) stress mediated autophagy in WS and normal aged cells is restored after transfection with wild type full length WRN, but deletion of the acidic domain from wild type WRN fails to restore autophagy. The acidic domain of WRNp was shown to regulate its transcriptional activity, and here, we show that it affects the transcription of certain proteins involved in autophagy and aging. Furthermore, siRNA mediated silencing of WRN in normal fibroblast WI-38 resulted in decrease of age related proteins Lamin A/C and Mre11.