Recombinogenic flap ligation mediated by human topoisomerase I

Aberration of eukaryotic topoisomerase I catalysis leads to potentially recombinogenic pathways by allowing the joining of heterologous DNA strands. Recently, a new ligation pathway (flap ligation) was presented for vaccinia virus topoisomerase I, in which blunt end cleavage complexes ligate the recessed end of duplex acceptors having a single-stranded 3'-tail. This reaction was suggested to play an important role in the repair of topoisomerase I-induced DNA double-strand breaks. Here, we characterize flap ligation mediated by human topoisomerase I. We demonstrate that cleavage complexes containing the enzyme at a blunt end allow invasion of a 3'-acceptor tail matching the scissile strand of the donor, which facilitates ligation of the recessed 5'-hydroxyl end. However, the reaction was strictly dependent on the length of double-stranded DNA of the donor complexes, and longer stretches of base-pairing inhibited strand invasion. The stabilization of the DNA helix was most probably provided by the covalently bound enzyme itself, since deleting the N-terminal domain of human topoisomerase I stimulated flap ligation. We suggest that stabilization of the DNA duplex upon enzyme binding may play an important role during normal topoisomerase I catalysis by preventing undesired strand transfer reactions. For flap ligation to function in a repair pathway, factors other than topoisomerase I, such as helicases, would be necessary to unwind the DNA duplex and allow strand invasion.     

RNA-directed repair of DNA double-strand breaks

DNA double-strand breaks (DSBs) are among the most deleterious DNA lesions, which if unrepaired or repaired incorrectly can cause cell death or genome instability that may lead to cancer. To counteract these adverse consequences, eukaryotes have evolved a highly orchestrated mechanism to repair DSBs, namely DNA-damage-response (DDR). DDR, as defined specifically in relation to DSBs, consists of multi-layered regulatory modes including DNA damage sensors, transducers and effectors, through which DSBs are sensed and then repaired via DNAprotein interactions. Unexpectedly, recent studies have revealed a direct role of RNA in the repair of DSBs, including DSB-induced small RNA (diRNA)-directed and RNA-templated DNA repair. Here, we summarize the recent discoveries of RNA-mediated regulation of DSB repair and discuss the potential impact of these novel RNA components of the DSB repair pathway on genomic stability and plasticity.     

Marker-free quantification of repair pathway utilization at Cas9-induced double-strand breaks

Genome integrity and genome engineering require efficient repair of DNA double-strand breaks (DSBs) by non-homologous end joining (NHEJ), homologous recombination (HR), or alternative end-joining pathways. Here we describe two complementary methods for marker-free quantification of DSB repair pathway utilization at Cas9-targeted chromosomal DSBs in mammalian cells. The first assay features the analysis of amplicon next-generation sequencing data using ScarMapper, an iterative break-associated alignment algorithm to classify individual repair products based on deletion size, microhomology usage, and insertions. The second assay uses repair pathway-specific droplet digital PCR assays (‘PathSig-dPCR’) for absolute quantification of signature DSB repair outcomes. We show that ScarMapper and PathSig-dPCR enable comprehensive assessment of repair pathway utilization in different cell models, after a variety of experimental perturbations. We use these assays to measure the differential impact of DNA end resection on NHEJ, HR and polymerase theta-mediated end joining (TMEJ) repair. These approaches are adaptable to any cellular model system and genomic locus where Cas9-mediated targeting is feasible. Thus, ScarMapper and PathSig-dPCR allow for systematic fate mapping of a targeted DSB with facile and accurate quantification of DSB repair pathway choice at endogenous chromosomal loci.     

DNA双链断裂的非同源末端连接修复

细胞内普遍存在的DNA双链断裂(DSB)可通过同源重组(HR)或非同源末端连接(NHEJ)修复。由于HR仅在存在相同染色体作为模板的时候进行,因此,NHEJ通常为主要的修复方式。在NHEJ中,DSB末端首先由Ku识别,接着由核酸酶、聚合酶在Ku与DNA-PKcs协助下加工,并由连接酶IVXRCC4-XLF连接。NHEJ底物类型多样,末端的修复常包含反复加工的过程,导致修复产物通常无法复原损伤前的序列。虽然无法确保准确修复DNA,NHEJ仍对维持基因组的稳定性具有重要的意义。对NHEJ的研究有助于理解癌症的发生机制并将促进癌症的治疗。     

DNA topoisomerase VI generates ATP-dependent double-strand breaks with two-nucleotide overhangs

A key step in the DNA transport by type II DNA topoisomerase is the formation of a double-strand break with the enzyme being covalently linked to the broken DNA ends (referred to as the cleavage complex). In the present study, we have analyzed the formation and structure of the cleavage complex catalyzed by Sufolobus shibatae DNA topoisomerase VI (topoVI), a member of the recently described type IIB DNA topoisomerase family. A purification procedure of a fully soluble recombinant topoVI was developed by expressing both subunits simultaneously in Escherichia coli. Using this recombinant enzyme, we observed that the formation of the double-strand breaks on supercoiled or linear DNA is strictly dependent on the presence of ATP or AMP-PNP. This result suggests that ATP binding is required to stabilize an enzyme conformation able to cleave the DNA backbone. The structure of cleavage complexes on a linear DNA fragment have been analyzed at the nucleotide level. Similarly to other type II DNA topoisomerases, topoVI is covalently attached to the 5'-ends of the broken DNA. However, sequence analysis of the double-strand breaks revealed that they are all characterized by staggered two-nucleotide long 5' overhangs, contrasting with the four-base staggered double-strand breaks catalyzed by type IIA DNA topoisomerases. While no clear consensus sequences surrounding the cleavage sites could be described, interestingly A and T nucleotides are highly represented on the 5' extensions, giving a first insight on the preferred sequences recognized by this type II DNA topoisomerase.     

Chromatin remodeling and repair of DNA double-strand breaks

Eukaryotic cells have developed conserved mechanisms to efficiently sense and repair DNA damage that results from constant chromosomal lesions. DNA repair has to proceed in the context of chromatin, and both histone-modifiers and ATP-dependent chromatin remodelers have been implicated in this process. Here, we review the current understanding and new hypotheses on how different chromatin-modifying activities function in DNA repair in yeast and metazoan cells.     

Modeling the repair of radiation-induced DNA double-strand breaks

A problem often overlooked in the study of the repair of radiation-induced DNA double-strand breads (DSBs) is the question of what the status of a regular site is in the DNA duplex immediately after a radiation treatment. Here, we suggest a mixed repair mechanism which consists of a gradual process and an instantaneous process. A comparison of the present kinetic model with those which have appeared in the literature shows that the former is a generalization of the latter. We have shown that different repair mechanisms may lead to equivalent mathematical representations. Therefore, care must be taken in interpreting the repair mechanism on the basis of the experimentally observed transient number of DSBs.     

DNA双链断裂修复与重症联合免疫缺陷

DNA双链断裂(double-strand breaks, DSBs)是细胞DNA损伤的主要类型,它的修复通过同源重组(HR)和非同源末端连接(NHEJ)两种机制实现.NHEJ是人和哺乳动物细胞DSBs修复的重要通路,主要由DNA依赖性蛋白激酶(DNA-PK)、X射线修复交叉互补蛋白4(XRCC4)、DNA连接酶Ⅳ、Artemis、XLF/Cernunnos和其它DNA损伤修复辅助因子组成.本文重点介绍了NHEJ机制主要成分的特性及其功能,以及这些组分的基因发生突变或缺失所引起的DSBs修复缺陷与辐射敏感性重症联合免疫缺陷(radiosensitive severe combined immunodeficiencies, RS-SCIDs).     

Multiple pathways for repair of DNA double-strand breaks in mammalian chromosomes

To study repair of DNA double-strand breaks (DSBs) in mammalian chromosomes, we designed DNA substrates containing a thymidine kinase (TK) gene disrupted by the 18-bp recognition site for yeast endonuclease I-SceI. Some substrates also contained a second defective TK gene sequence to serve as a genetic donor in recombinational repair. A genomic DSB was induced by introducing endonuclease I-SceI into cells containing a stably integrated DNA substrate. DSB repair was monitored by selection for TK-positive segregants. We observed that intrachromosomal DSB repair is accomplished with nearly equal efficiencies in either the presence or absence of a homologous donor sequence. DSB repair is achieved by nonhomologous end-joining or homologous recombination, but rarely by nonconservative single-strand annealing. Repair of a chromosomal DSB by homologous recombination occurs mainly by gene conversion and appears to require a donor sequence greater than a few hundred base pairs in length. Nonhomologous end-joining events typically involve loss of very few nucleotides, and some events are associated with gene amplification at the repaired locus. Additional studies revealed that precise religation of DNA ends with no other concomitant sequence alteration is a viable mode for repair of DSBs in a mammalian genome.     

Contribution of topoisomerase I to conversion of single-strand into double-strand DNA breaks

An in vitro system composed of nicked pBR322 DNA and purified topoisomerase I was employed to study the efficiency of the topoisomerase I-driven single-strand to double-strand DNA breaks conversion. At 1.4 × 10⁵ topoisomerase I activity units per mg DNA about 20% single-strand nicks were converted into double-strand breaks during 30 min due to topoisomerase I action. Camptothecin inhibited the conversion. The conversion was also inhibited when the relaxing activity of the used topoisomerase I was increased by phosphorylation of the enzyme with casein kinase 2. The presented data suggest that topoisomerase I may be involved in production of double-stranded breaks in irradiated cells and that this process positively depends on the amount of topoisomerase I but not on its phosphorylation state.     

Repair of chromosomal double-strand breaks by precise ligation in human cells

Double-strand breaks (DSBs), a common type of DNA lesion, occur daily in human cells as a result of both endogenous and exogenous damaging agents. DSBs are repaired in two general ways: by the homology-dependent, error-free pathways of homologous recombination (HR) and by the homology-independent, error-prone pathways of nonhomologous end-joining (NHEJ), with NHEJ predominating in most cells. DSBs with compatible ends can be re-joined in vitro with DNA ligase alone, which raises the question of whether such DSBs require the more elaborate machinery of NHEJ to be repaired in cells. Here we report that chromosomal DSBs with compatible ends introduced by the rare-cutting endonuclease, ISceI, are repaired by precise ligation nearly 100% of the time in human cells. Precise ligation depends on the classical NHEJ components Ku70, XRCC4, and DNA ligase IV, since siRNA knockdowns of these factors significantly reduced the efficiency of precise ligation. Interestingly, knockdown of the tumor suppressors p53 or BRCA1 showed similar effects as the knockdowns of NHEJ factors. In contrast, knockdown of components involved in alternative NHEJ, mismatch repair, nucleotide excision repair, and single-strand break repair did not reduce precise ligation. In summary, our results demonstrate that DSBs in human cells are efficiently repaired by precise ligation, which requires classical NHEJ components and is enhanced by p53 and BRCA1.     

Proteasome involvement in the repair of DNA double-strand breaks

Affinity purification of the yeast 19S proteasome revealed the presence of Sem1 as a subunit. Its human homolog, DSS1, was found likewise to copurify with the human 19S proteasome. DSS1 is known to associate with the tumor suppressor protein BRCA2 involved in repair of DNA double-strand breaks (DSBs). We demonstrate that Sem1 is required for efficient repair of an HO-generated yeast DSB using both homologous recombination (HR) and nonhomologous end joining (NHEJ) pathways. Deletion of SEM1 or genes encoding other nonessential 19S or 20S proteasome subunits also results in synthetic growth defects and hypersensitivity to genotoxins when combined with mutations in well-established DNA DSB repair genes. Chromatin immunoprecipitation showed that Sem1 is recruited along with the 19S and 20S proteasomes to a DSB in vivo, and this recruitment is dependent on components of both the HR and NHEJ repair pathways, suggesting a direct role of the proteasome in DSB repair.     

Postreplicative recruitment of cohesin to double-strand breaks is required for DNA repair

Chromosome stability depends on accurate chromosome segregation and efficient DNA double-strand break (DSB) repair. Sister chromatid cohesion, established during S phase by the protein complex cohesin, is central to both processes. In the absence of cohesion, chromosomes missegregate and G2-phase DSB repair fails. Here, we demonstrate that G2-phase repair also requires the presence of cohesin at the damage site. Cohesin components are shown to be recruited to extended chromosome regions surrounding DNA breaks induced during G2. We find that in the absence of functional cohesin-loading proteins (Scc2/Scc4), the accumulation of cohesin at DSBs is abolished and repair is defective, even though sister chromatids are connected by S phase generated cohesion. Evidence is also provided that DSB induction elicits establishment of sister chromatid cohesion in G2, implicating that damage-recruited cohesin facilitates DNA repair by tethering chromatids.     

Efficient repair of bleomycin-induced double-strand breaks in barley ribosomal genes

Ability of barley ribosomal genes to cope with damage produced in vivo by the radiomimetic agent bleomycin was investigated. Repair kinetics of bleomycin-induced double-strand breaks in ribosomal and total genomic DNA was compared. Induction and repair of double-strand breaks in defined regions of the ribosomal genes was also analyzed. Preferential sensitivity of barley linker DNA towards bleomycin treatment in vivo was established. Relatively higher yield of initially induced double-strand breaks in genomic DNA in comparison to ribosomal DNA was also found. Fragments containing intergenic spacers of barley rRNA genes displayed higher sensitivity to bleomycin than the coding sequences. No heterogeneity in the repair of DSB between transcribed and non-transcribed regions of ribosomal genes was detected. Data indicate that DSB repair in barley rDNA, although more efficient than in genomic DNA, does not correlate with the activity of nucleolus organizer regions.     

Mismatch repair converts AID-instigated nicks to double-strand breaks for antibody class-switch recombination

Mismatch repair (MMR) proteins are important for antibody class-switch recombination (CSR), but their roles are unknown. We propose a model for the function of MMR in CSR in which MMR proteins convert single-strand nicks instigated by activation-induced cytidine deaminase (AID) into the double-strand breaks (DSBs) that are required for CSR. This model does not invoke any novel functions for MMR but simply posits that, owing to numerous single-strand nicks in the switch (S) regions of both DNA strands, when MMR proteins are recruited by U:G mismatches, they excise one strand of DNA and soon reach a nick on the opposite strand. This halts excision activity and creates a DSB. This model explains why B cells that lack either S mu and MSH2 or UNG and MSH2 cannot undergo CSR.     

Protein phosphatase PP6 is required for homology-directed repair of DNA double-strand breaks

DNA double-strand breaks (DSBs) are among the most lethal lesions associated with genome stability, which, when destabilized, predisposes organs to cancers. DSBs are primarily fixed either with little fidelity by non-homologous end joining (NHEJ) repair or with high fidelity by homology-directed repair (HDR). The phosphorylated form of H2AX on serine 139 (γ-H2AX) is a marker of DSBs. In this study, we explored if the protein phosphatase PP6 is involved in DSB repair by depletion of its expression in human cancer cell lines, and determined PP6 expression in human breast cancer tissues by immunohistochemistry staining. We found that bacterially produced PP6c (the catalytic subunit of PP6)-containing heterotrimeric combinations exhibit phosphatase activity against γ-H2AX in the in vitro phosphatase assays. Depletion of PP6c or PP6R2 led to persistent high levels of γ-H2AX after DNA damage and a defective HDR. Chromatin immunoprecipitation assays demonstrated that PP6c was recruited to the region adjacent to the DSB sites. Expression of PP6c, PP6R2 and PP6R3 in human breast tumors was significantly lower than those in benign breast diseases. Taken together, our results suggest that γ-H2AX is a physiological substrate of PP6 and PP6 is required for HDR and its expression may harbor a protective role during the development of breast cancer.Key words: protein phosphatase, PP6, γ-H2AX, DNA double-strand break, homology-directed repair     

A kinetic analysis of the repair of radiation-induced DNA double-strand breaks

The repair of radiation-induced DNA double-strand breaks (DSBs) is analyzed kinetically. It is assumed that a fraction of the damaged sites in the DNA duplex are irreparable. The kinetic model takes the effect of radiation dose into account. The analysis of the available experimental data reveals that, although the number of irreparable DSBs is a quadratic function of radiation dose, the normalized number of irreparable DSBs correlates linearly with this variable.     

Protein phosphatase PP6 is required for homology-directed repair of DNA double-strand breaks

DNA double-strand breaks (DSBs) are among the most lethal lesions associated with genome stability which, when destabilized, predisposes organs to cancers. DSBs are primarily fixed either with little fidelity by non-homologous end joining (NHEJ) repair or with high fidelity by homology-directed repair (HDR). The phosphorylated form of H2AX on serine 139 (g-H2AX) is a marker of DSBs. In this study, we explored if the protein phosphatase PP6 is involved in DSB repair by depletion of its expression in human cancer cell lines, and determined PP6 expression in human breast cancer tissues by immunohistochemistry staining. We found that bacterially-produced PP6c (the catalytic subunit of PP6)-containing heterotrimeric combinations exhibit phosphatase activity against g-H2AX in the in vitro phosphatase assays. Depletion of PP6c or PP6R2 led to persistent high levels of g-H2AX after DNA damage and a defective HDR. Chromatin immunoprecipitation assays demonstrated that PP6c was recruited to the region adjacent to the DSB sites. Expression of PP6c, PP6R2, and PP6R3 in human breast tumors was significantly lower than those in benign breast diseases. Taken together, our results suggest that g-H2AX is a physiological substrate of PP6, and PP6 is required for HDR and its expression may harbor a protective role during the development of breast cancer.