Explore the vast range of titles available.

The resolution of joint molecules that link recombining sister chromatids is essential for chromosome segregation. Here, we determine the fate of unresolved recombination intermediates arising in cells lacking two nucleases required for resolution ( GEN1 –/– knockout cells depleted of MUS81). We find that intermediates persist until mitosis and form a distinct class of anaphase bridges, which we term homologous recombination ultra-fine bridges (HR-UFBs). HR-UFBs are distinct from replication stress-associated UFBs, which arise at common fragile sites, and from centromeric UFBs. HR-UFBs are processed by BLM helicase to generate single-stranded RPA-coated bridges that are broken during mitosis. In the next cell cycle, DNA breaks activate the DNA damage checkpoint response, and chromosome fusions arise by non-homologous end joining. Consequently, the cells undergo cell cycle delay and massive cell death. These results lead us to present a model detailing how unresolved recombination intermediates can promote DNA damage and chromosomal instability. Chan et al. show that unresolved recombination intermediates form a previously unappreciated type of ultra-fine bridge. These bridges are broken upon cell division, leading to chromosome breaks and instability.

Poly(ADP-ribose) polymerase (PARP) inhibitors are used in the clinic to treat BRCA -deficient breast, ovarian and prostate cancers. As their efficacy is potentiated by loss of the nucleotide salvage factor DNPH1 there is considerable interest in the development of highly specific small molecule DNPH1 inhibitors. Here, we present X-ray crystal structures of dimeric DNPH1 bound to its substrate hydroxymethyl deoxyuridine monophosphate (hmdUMP). Direct interaction with the hydroxymethyl group is important for substrate positioning, while conserved residues surrounding the base facilitate target discrimination. Glycosidic bond cleavage is driven by a conserved catalytic triad and proceeds via a two-step mechanism involving formation and subsequent disruption of a covalent glycosyl-enzyme intermediate. Mutation of a previously uncharacterised yet conserved glutamate traps the intermediate in the active site, demonstrating its role in the hydrolytic step. These observations define the enzyme’s catalytic site and mechanism of hydrolysis, and provide important insights for inhibitor discovery. Inactivation of DNPH1 leads to hmdU incorporation into DNA, sensitising BRCA -deficient cells to PARP inhibitors. Crystal structures of DNPH1 bound to hmdU monophosphate reveal a two-step mechanism for hydrolysis via a glycosyl-enzyme intermediate.

The RecQ DNA helicase WRN is a synthetic lethal target for cancer cells with microsatellite instability (MSI), a form of genetic hypermutability that arises from impaired mismatch repair 1 – 4 . Depletion of WRN induces widespread DNA double-strand breaks in MSI cells, leading to cell cycle arrest and/or apoptosis. However, the mechanism by which WRN protects MSI-associated cancers from double-strand breaks remains unclear. Here we show that TA-dinucleotide repeats are highly unstable in MSI cells and undergo large-scale expansions, distinct from previously described insertion or deletion mutations of a few nucleotides 5 . Expanded TA repeats form non-B DNA secondary structures that stall replication forks, activate the ATR checkpoint kinase, and require unwinding by the WRN helicase. In the absence of WRN, the expanded TA-dinucleotide repeats are susceptible to cleavage by the MUS81 nuclease, leading to massive chromosome shattering. These findings identify a distinct biomarker that underlies the synthetic lethal dependence on WRN, and support the development of therapeutic agents that target WRN for MSI-associated cancers. In cells with microsatellite instability, expanded TA-dinucleotide repeats form cruciform structures that stall replication forks and cause chromosome shattering in the absence of the WRN helicase.

HERC2 regulates the retention of repair proteins 53BP1, RAP80 and BRCA1 on damaged chromosomes in response to ionizing radiation by forming a complex with the ubiquitin ligases RNF8 and RNF168. Hecr2 deficiency leads to radiosensitivity. Regulatory ubiquitylation is emerging as an important mechanism to protect genome integrity in cells exposed to DNA damage 1 , 2 , 3 , 4 , 5 , 6 , 7 , 8 , 9 . However, the spectrum of known ubiquitin regulators of the DNA damage response (DDR) is limited and their functional interplay is poorly understood. Here, we identify HERC2 as a factor that regulates ubiquitin-dependent retention of repair proteins on damaged chromosomes. In response to ionising radiation (IR), HERC2 forms a complex with RNF8, a ubiquitin ligase involved in the DDR 3 , 4 , 5 , 6 . The HERC2–RNF8 interaction requires IR-inducible phosphorylation of HERC2 at Thr 4827, which in turn binds to the forkhead-associated (FHA) domain of RNF8. Mechanistically, we provide evidence that HERC2 facilitates assembly of the ubiquitin-conjugating enzyme Ubc13 with RNF8, thereby promoting DNA damage-induced formation of Lys 63-linked ubiquitin chains. We also show that HERC2 interacts with, and maintains the levels of, RNF168, another ubiquitin ligase operating downstream of RNF8 (Refs 7 , 8 ). Consequently, knockdown of HERC2 abrogates ubiquitin-dependent retention of repair factors such as 53BP1, RAP80 and BRCA1. Together with the increased radiosensitivity of HERC2-depleted cells, these results uncover a regulatory layer in the orchestration of protein interactions on damaged chromosomes and they underscore the role of ubiquitin-mediated signalling in genome maintenance.

Pathway choice is a critical event in the repair of DNA double-strand breaks. In a recent paper published in Nature, Orthwein et al. define a mechanism by which homologous recombination is controlled in G1 cells to favor non-homologous end joining.

LEDGF (p75) is a chromatin-binding protein implicated in cancer, autoimmune disease and HIV-1 pathogenesis, but its cellular function was still unclear. Now LEDGF is found to have a role in the repair of DNA double-stranded breaks via homologous recombination, promoting end resection by CtIP. Lens epithelium–derived growth factor p75 splice variant (LEDGF) is a chromatin-binding protein known for its antiapoptotic activity and ability to direct human immunodeficiency virus into active transcription units. Here we show that LEDGF promotes the repair of DNA double-strand breaks (DSBs) by the homologous recombination repair pathway. Depletion of LEDGF impairs the recruitment of C-terminal binding protein interacting protein (CtIP) to DNA DSBs and the subsequent CtIP-dependent DNA-end resection. LEDGF is constitutively associated with chromatin through its Pro-Trp-Trp-Pro (PWWP) domain that binds preferentially to epigenetic methyl-lysine histone markers characteristic of active transcription units. LEDGF binds CtIP in a DNA damage–dependent manner, thereby enhancing its tethering to the active chromatin and facilitating its access to DNA DSBs. These data highlight the role of PWWP-domain proteins in DNA repair and provide a molecular explanation for the antiapoptotic and cancer cell survival–activities of LEDGF.

Cancer and cell senescence Cancer is commonly thought of as uncontrolled cellular proliferation, but in the early stages of many cancers, oncogene expression is associated with cellular senescence. A possible explanation for this has now been found. Two groups report a link between oncogene-induced senescence and the DNA damage response. Activated oncogenes can cause aberrant DNA replication and thereby DNA damage that can lead to cell senescence. Cellular senescence was found previously to be a barrier to tumorigenesis in vivo , so oncogene-induced senescence may be an innate defence against cancer. But its effectiveness is often disabled by further mutations. Understanding the relationship between cell senescence and tumour formation may aid in the development of diagnostic and prognostic tools based on senescence markers. One of two papers linking oncogene-induced senescence and the DNA damage response. Activated oncogenes can cause aberrant DNA replication and thereby DNA damage, which leads to cellular senescence. This response can block tumour progression, but is often disabled by further alterations. Recent studies have indicated the existence of tumorigenesis barriers that slow or inhibit the progression of preneoplastic lesions to neoplasia. One such barrier involves DNA replication stress, which leads to activation of the DNA damage checkpoint and thereby to apoptosis or cell cycle arrest 1 , 2 , whereas a second barrier is mediated by oncogene-induced senescence 3 , 4 , 5 , 6 . The relationship between these two barriers, if any, has not been elucidated. Here we show that oncogene-induced senescence is associated with signs of DNA replication stress, including prematurely terminated DNA replication forks and DNA double-strand breaks. Inhibiting the DNA double-strand break response kinase ataxia telangiectasia mutated (ATM) suppressed the induction of senescence and in a mouse model led to increased tumour size and invasiveness. Analysis of human precancerous lesions further indicated that DNA damage and senescence markers cosegregate closely. Thus, senescence in human preneoplastic lesions is a manifestation of oncogene-induced DNA replication stress and, together with apoptosis, provides a barrier to malignant progression.

Chromosomal instability (CIN) is common in solid tumours and fuels evolutionary adaptation and poor prognosis by increasing intratumour heterogeneity. Systematic characterization of driver events in the TRACERx non-small-cell lung cancer (NSCLC) cohort identified that genetic alterations in six genes, including FAT1 , result in homologous recombination (HR) repair deficiencies and CIN. Using orthogonal genetic and experimental approaches, we demonstrate that FAT1 alterations are positively selected before genome doubling and associated with HR deficiency. FAT1 ablation causes persistent replication stress, an elevated mitotic failure rate, nuclear deformation and elevated structural CIN, including chromosome translocations and radial chromosomes. FAT1 loss contributes to whole-genome doubling (a form of numerical CIN) through the dysregulation of YAP1. Co-depletion of YAP1 partially rescues numerical CIN caused by FAT1 loss but does not relieve HR deficiencies, nor structural CIN. Importantly, overexpression of constitutively active YAP1 5SA is sufficient to induce numerical CIN. Taken together, we show that FAT1 loss in NSCLC attenuates HR and exacerbates CIN through two distinct downstream mechanisms, leading to increased tumour heterogeneity. Lu et al. perform systematic functional analyses using data from the TRACERx cohort of patients with non-small-cell lung cancer and delineate how FAT1 regulates homologous recombination repair, chromosomal instability and whole-genome doubling with distinct mechanisms.

The molecular events occurring following the disruption of DNA replication forks are poorly characterized, despite extensive use of replication inhibitors such as hydroxyurea in the treatment of malignancies. Here, we identify a key role for the FBH1 helicase in mediating DNA double-strand break formation following replication inhibition. We show that FBH1-deficient cells are resistant to killing by hydroxyurea, and exhibit impaired activation of the pro-apoptotic factor p53, consistent with decreased DNA double-strand break formation. Similar findings were obtained in murine ES cells carrying disrupted alleles of Fbh1. We also show that FBH1 through its helicase activity co-operates with the MUS81 nuclease in promoting the endonucleolytic DNA cleavage following prolonged replication stress. Accordingly, MUS81 and EME1-depleted cells show increased resistance to the cytotoxic effects of replication stress. Our data suggest that FBH1 helicase activity is required to eliminate cells with excessive replication stress through the generation of MUS81-induced DNA double-strand breaks. DNA replication stress promotes genome instability and cell death. Here Fugger et al. describe how FBH1, via its helicase activity, is required to eliminate cells with excessive DNA replication stress, through the generation of MUS81-induced DNA double-strand breaks.

Nature Cell Biol. 12, 80–81 (2010); published online 20 December 2009; corrected after print, 10 March 2010 In the version of this Letter initially published, an author, Claudia Lukas, was omitted. The author list and author's affiliations have been changed to: Simon Bekker-Jensen1,3,4, Jannie Rendtlew Danielsen1,3,4, Kasper Fugger1, Irina Gromova2, Annika Nerstedt1, Claudia Lukas1, Jiri Bartek1, Jiri Lukas1 & Niels Mailand1,3