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。     

TDP1 promotes assembly of non-homologous end joining protein complexes on DNA

The repair of DNA double-strand breaks (DSB) is central to the maintenance of genomic integrity. In tumor cells, the ability to repair DSBs predicts response to radiation and many cytotoxic anti-cancer drugs. DSB repair pathways include homologous recombination and non-homologous end joining (NHEJ). NHEJ is a template-independent mechanism, yet many NHEJ repair products carry limited genetic changes, which suggests that NHEJ includes mechanisms to minimize error. Proteins required for mammalian NHEJ include Ku70/80, the DNA-dependent protein kinase (DNA-PKcs), XLF/Cernunnos and the XRCC4:DNA ligase IV complex. NHEJ also utilizes accessory proteins that include DNA polymerases, nucleases, and other end-processing factors. In yeast, mutations of tyrosyl-DNA phosphodiesterase (TDP1) reduced NHEJ fidelity. TDP1 plays an important role in repair of topoisomerase-mediated DNA damage and 3′-blocking DNA lesions, and mutation of the human TDP1 gene results in an inherited human neuropathy termed SCAN1. We found that human TDP1 stimulated DNA binding by XLF and physically interacted with XLF to form TDP1:XLF:DNA complexes. TDP1:XLF interactions preferentially stimulated TDP1 activity on dsDNA as compared to ssDNA. TDP1 also promoted DNA binding by Ku70/80 and stimulated DNA-PK activity. Because Ku70/80 and XLF are the first factors recruited to the DSB at the onset of NHEJ, our data suggest a role for TDP1 during the early stages of mammalian NHEJ.     

TDP1 is required for efficient non-homologous end joining in human cells

Tyrosyl-DNA phosphodiesterase 1 (TDP1) can remove a wide variety of 3′ and 5′ terminal DNA adducts. Genetic studies in yeast identified TDP1 as a regulator of non-homologous end joining (NHEJ) fidelity in the repair of double-strand breaks (DSBs) lacking terminal adducts. In this communication, we show that TDP1 plays an important role in joining cohesive DSBs in human cells. To investigate the role of TDP1 in NHEJ in live human cells we used CRISPR/cas9 to produce TDP1-knockout (TDP1-KO) HEK-293 cells. As expected, human TDP1-KO cells were highly sensitive to topoisomerase poisons and ionizing radiation. Using a chromosomally-integrated NHEJ reporter substrate to compare end joining between wild type and TDP1-KO cells, we found that TDP1-KO cells have a 5-fold reduced ability to repair I-SceI-generated DSBs. Extracts prepared from TDP1-KO cells had reduced NHEJ activity in vitro, as compared to extracts from wild type cells. Analysis of end-joining junctions showed that TDP1 deficiency reduced end-joining fidelity, with a significant increase in insertion events, similar to previous observations in yeast. It has been reported that phosphorylation of TDP1 serine 81 (TDP1-S81) by ATM and DNA-PK stabilizes TDP1 and recruits TDP1 to sites of DNA damage. We found that end joining in TDP1-KO cells was partially restored by the non-phosphorylatable mutant TDP1-S81A, but not by the phosphomimetic TDP1-S81E. We previously reported that TDP1 physically interacted with XLF. In this study, we found that XLF binding by TDP1 was reduced 2-fold by the S81A mutation, and 10-fold by the S81E phosphomimetic mutation. Our results demonstrate a novel role for TDP1 in NHEJ in human cells. We hypothesize that TDP1 participation in human NHEJ is mediated by interaction with XLF, and that TDP1-XLF interactions and subsequent NHEJ events are regulated by phosphorylation of TDP1-S81.     

A critical role for the C-terminus of Nej1 protein in Lif1p association, DNA binding and non-homologous end-joining

A predominant pathway implicated in repair of DNA double-strand breaks (DSBs) is the evolutionarily conserved non-homologous end-joining (NHEJ) pathway. Among the major constituents of this pathway in Saccharomyces cerevisiae is Nej1p, for which a biochemical function has yet to be determined. In this work we demonstrate that Nej1p exhibits a DNA binding activity (KD approximately 1.8 microM) comparable to Lif1p. Although binding is enhanced with larger substrates (>300 bp), short approximately 20 bp substrates can suffice. This DNA binding activity is the first biochemical evidence supporting the idea that Nej1p plays a direct role in the repair of double-strand breaks. The C-terminus of Nej1p is required for interaction with Lif1p and is sufficient for DNA binding. Structural characterization reveals that Nej1p exists as a dimer, and that residues 1-244 are sufficient for dimer formation. Nej1p (aa 1-244) is shown to be defective in end-joining in vivo. Preliminary functional and structural studies on the Nej1p-Lif1p complex suggest that the proteins stably co-purify and the complex binds DNA with a higher affinity than each independent component. The significance of these results is discussed with reference to current literature on Nej1p and other end-joining factors (mammalian and yeast), specifically the recently identified putative mammalian homologue of Nej1p, XLF/Cernunnos.     

Delineation of the Xrcc4-interacting Region in the Globular Head Domain of Cernunnos/XLF

In mammals, the majority of DNA double-strand breaks are processed by the nonhomologous end-joining (NHEJ) pathway, composed of seven factors: Ku70, Ku80, DNA-PKcs, Artemis, Xrcc4 (X4), DNA-ligase IV (L4), and Cernunnos/XLF. Cernunnos is part of the ligation complex, constituted by X4 and L4. To improve our knowledge on the structure and function of Cernunnos, we performed a systematic mutagenesis study on positions selected from an analysis of the recent three-dimensional structures of this factor. Ten of 27 screened mutants were nonfunctional in several DNA repair assays. Outside amino acids critical for the expression and stability of Cernunnos, we identified three amino acids (Arg⁶⁴, Leu⁶⁵, and Leu¹¹⁵) essential for the interaction with X4 and the proper function of Cernunnos. Docking the crystal structures of the two factors further validated this probable interaction surface of Cernunnos with X4.     

Ku recruits XLF to DNA double-strand breaks

XRCC4-like factor (XLF)--also known as Cernunnos--has recently been shown to be involved in non-homologous end-joining (NHEJ), which is the main pathway for the repair of DNA double-strand breaks (DSBs) in mammalian cells. XLF is likely to enhance NHEJ by stimulating XRCC4-ligase IV-mediated joining of DSBs. Here, we report mechanistic details of XLF recruitment to DSBs. Live cell imaging combined with laser micro-irradiation showed that XLF is an early responder to DSBs and that Ku is essential for XLF recruitment to DSBs. Biochemical analysis showed that Ku-XLF interaction occurs on DNA and that Ku stimulates XLF binding to DNA. Unexpectedly, XRCC4 is dispensable for XLF recruitment to DSBs, although photobleaching analysis showed that XRCC4 stabilizes the binding of XLF to DSBs. Our observations showed the direct involvement of XLF in the dynamic assembly of the NHEJ machinery and provide mechanistic insights into DSB recognition.     

Role and regulation of human XRCC4-like factor/cernunnos

In mammalian cells, non-homologous end joining (NHEJ) is the major double strand break (DSB) repair mechanism during the G(1) phase of the cell cycle. It also contributes to DSB repair during the S and G(2) phases. Ku heterodimer, DNA PKcs, XRCC4 and DNA Ligase IV constitute the core NHEJ machinery, which joins directly ligatable ends. XRCC4-like factor/Cernunnos (XLF/Cer) is a recently discovered interaction partner of XRCC4. Current evidence suggests the following model for the role of XLF/Cer in NHEJ: after DSB induction, the XRCC4-DNA Ligase IV complex promotes efficient accumulation of XLF/Cer at DNA damage sites via constitutive interaction of the XRCC4 and XLF/Cer head domains and dependent on components of the DNA PK complex. Ku alone can stabilise the association of XLF/Cer with DNA ends. XLF/Cer stimulates ligation of complementary and non-complementary DNA ends by XRCC4-DNA Ligase IV. This activity involves the carboxy-terminal DNA binding region of XLF/Cer and could occur via different, non-exclusive modes: (i) enhancement of the stability of the XRCC4-DNA Ligase IV complex on DNA ends by XLF/Cer, (ii) modulation of the efficiency and/or specificity of DNA Ligase IV by binding of XLF/Cer to the XRCC4-DNA Ligase IV complex, (iii) promotion of the alignment of blunt or other non-complementary DNA ends by XLF/Cer for ligation. XLF/Cer promotes the preservation of 3' overhangs, restricts nucleotide loss and thereby promotes accuracy of DSB joining by XRCC4-DNA Ligase IV during NHEJ and V(D)J recombination.     

DNA-PK: A dynamic enzyme in a versatile DSB repair pathway

DNA double stranded breaks (DSBs) are the most cytoxic DNA lesion as the inability to properly repair them can lead to genomic instability and tumorigenesis. The prominent DSB repair pathway in humans is non-homologous end-joining (NHEJ). In the simplest sense, NHEJ mediates the direct re-ligation of the broken DNA molecule. However, NHEJ is a complex and versatile process that can repair DSBs with a variety of damages and ends via the utilization of a significant number of proteins. In this review we will describe the important factors and mechanisms modulating NHEJ with emphasis given to the versatility of this repair process and the DNA-PK complex.     

Two distinct long-range synaptic complexes promote different aspects of end processing prior to repair of DNA breaks by non-homologous end joining

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APLF and long non-coding RNA NIHCOLE promote stable DNA synapsis in non-homologous end joining

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