Project description:DNA double-strand break (DSB) repair is not only key to genome stability but is also an important anticancer target. Through an shRNA library-based screening, we identified ubiquitin-conjugating enzyme H7 (UbcH7, also known as Ube2L3), a ubiquitin E2 enzyme, as a critical player in DSB repair. UbcH7 regulates both the steady-state and replicative stress-induced ubiquitination and proteasome-dependent degradation of the tumor suppressor p53-binding protein 1 (53BP1). Phosphorylation of 53BP1 at the N terminus is involved in the replicative stress-induced 53BP1 degradation. Depletion of UbcH7 stabilizes 53BP1, leading to inhibition of DSB end resection. Therefore, UbcH7-depleted cells display increased nonhomologous end-joining and reduced homologous recombination for DSB repair. Accordingly, UbcH7-depleted cells are sensitive to DNA damage likely because they mainly used the error-prone nonhomologous end-joining pathway to repair DSBs. Our studies reveal a novel layer of regulation of the DSB repair choice and propose an innovative approach to enhance the effect of radiotherapy or chemotherapy through stabilizing 53BP1.

Project description:P53-binding protein 1 (53BP1) plays critical roles in DNA double strand break (DSB) repair by promoting non-homologous end joining (NHEJ), and loss of 53BP1 abolishes PARPi sensitivity in BRCA1-deficient cells by restoring homologous recombination (HR). 53BP1 is one of the proteins initially recruited to sites of DSBs via recognition of H4K20me2 through the Tudor-UDR domain and H2AK15ub through the UDR motif. Although extensive studies have been conducted, it remains unclear how the post-translational modification of 53BP1 affects DSB repair pathway choice. Here, we identified 53BP1 as an acetylated protein and determined that acetylation of 53BP1 inhibit NHEJ and promote HR by negatively regulating 53BP1 recruitment to DSBs. Mechanistically, CBP-mediated acetylation of K1626/1628 in the UDR motif disrupted the interaction between 53BP1 and nucleosomes, subsequently blocking the recruitment of 53BP1 and its downstream factors PTIP and RIF1 to DSBs. Hyperacetylation of 53BP1, similar to depletion of 53BP1, restored PARPi resistance in BRCA1-deficient cells. Interestingly, 53BP1 acetylation was tightly regulated by HDAC2 to maintain balance between the HR and NHEJ pathways. Together, our results demonstrate that the acetylation status of 53BP1 plays a key role in its recruitment to DSBs and reveal how specific 53BP1 modification modulates the choice of DNA repair pathway.

Project description:Cell-cycle phase is a critical determinant of the choice between DNA damage repair by nonhomologous end-joining (NHEJ) or homologous recombination (HR). Here, we report that double-strand breaks (DSBs) induce ATM-dependent MOF (a histone H4 acetyl-transferase) phosphorylation (p-T392-MOF) and that phosphorylated MOF colocalizes with ?-H2AX, ATM, and 53BP1 foci. Mutation of the phosphorylation site (MOF-T392A) impedes DNA repair in S and G2 phase but not G1 phase cells. Expression of MOF-T392A also blocks the reduction in DSB-associated 53BP1 seen in wild-type S/G2 phase cells, resulting in enhanced 53BP1 and reduced BRCA1 association. Decreased BRCA1 levels at DSB sites correlates with defective repairosome formation, reduced HR repair, and decreased cell survival following irradiation. These data support a model whereby ATM-mediated MOF-T392 phosphorylation modulates 53BP1 function to facilitate the subsequent recruitment of HR repair proteins, uncovering a regulatory role for MOF in DSB repair pathway choice during S/G2 phase.

Project description:Cellular DNA is constantly under threat from internal and external insults, consequently multiple pathways have evolved to maintain chromosomal fidelity. Our previous studies revealed that chronic stress, mediated by continuous stimulation of the ?2-adrenergic-?arrestin-1 signaling axis suppresses activity of the tumor suppressor p53 and impairs genomic integrity. In this pathway, ?arrestin-1 (?arr1) acts as a molecular scaffold to promote the binding and degradation of p53 by the E3-ubiquitin ligase, MDM2. We sought to determine whether ?arr1 plays additional roles in the repair of DNA damage. Here we demonstrate that in mice ?arr1 interacts with p53-binding protein 1 (53BP1) with major consequences for the repair of DNA double-strand breaks. 53BP1 is a principle component of the DNA damage response, and when recruited to the site of double-strand breaks in DNA, 53BP1 plays an important role coordinating repair of these toxic lesions. Here, we report that ?arr1 directs 53BP1 degradation by acting as a scaffold for the E3-ubiquitin ligase Rad18. Consequently, knockdown of ?arr1 stabilizes 53BP1 augmenting the number of 53BP1 DNA damage repair foci following exposure to ionizing radiation. Accordingly, ?arr1 loss leads to a marked increase in irradiation resistance both in cells and in vivo. Thus, ?arr1 is an important regulator of double strand break repair, and disruption of the ?arr1/53BP1 interaction offers an attractive strategy to protect cells against high levels of exposure to ionizing radiation.

Project description:53BP1 is a chromatin-binding protein that regulates the repair of DNA double-strand breaks by suppressing the nucleolytic resection of DNA termini1,2. This function of 53BP1 requires interactions with PTIP3 and RIF14-9, the latter of which recruits REV7 (also known as MAD2L2) to break sites10,11. How 53BP1-pathway proteins shield DNA ends is currently unknown, but there are two models that provide the best potential explanation of their action. In one model the 53BP1 complex strengthens the nucleosomal barrier to end-resection nucleases12,13, and in the other 53BP1 recruits effector proteins with end-protection activity. Here we identify a 53BP1 effector complex, shieldin, that includes C20orf196 (also known as SHLD1), FAM35A (SHLD2), CTC-534A2.2 (SHLD3) and REV7. Shieldin localizes to double-strand-break sites in a 53BP1- and RIF1-dependent manner, and its SHLD2 subunit binds to single-stranded DNA via OB-fold domains that are analogous to those of RPA1 and POT1. Loss of shieldin impairs non-homologous end-joining, leads to defective immunoglobulin class switching and causes hyper-resection. Mutations in genes that encode shieldin subunits also cause resistance to poly(ADP-ribose) polymerase inhibition in BRCA1-deficient cells and tumours, owing to restoration of homologous recombination. Finally, we show that binding of single-stranded DNA by SHLD2 is critical for shieldin function, consistent with a model in which shieldin protects DNA ends to mediate 53BP1-dependent DNA repair.

Project description:Oncogenic Ras expression is associated with activation of the DNA damage response (DDR) pathway, as evidenced by elevated DNA damage, primarily DNA double-strand breaks (DSBs), and activation of DNA damage checkpoints, which in primary human cells leads to entry into senescence. DDR activation is viewed as a physiological barrier against uncontrolled proliferation in oncogenic Ras-expressing cells, and arises in response to genotoxic stress due to the production of reactive oxygen species that damage DNA and to hyper-replication stress. Although oncogene-induced senescence (OIS) is considered a tumor suppressor mechanism, the accumulation of DNA damage in senescent cells is thought to cause genomic instability, eventually allowing secondary hits in the genome that promote tumorigenesis. To date, the molecular mechanisms behind DNA repair defects during OIS remain poorly understood. Here, we show that oncogenic Ras expression in human primary cells results in the downregulation of BRCA1 and 53BP1, two key factors in DNA DSB repair by homologous recombination and non-homologous end joining, respectively. As a consequence, Ras-induced senescent cells are hindered in their ability to recruit BRCA1 and 53BP1 to DNA damage sites. Whereas BRCA1 is downregulated at transcripts levels, 53BP1 loss is caused by activation of cathepsin L-mediated degradation of 53BP1 protein. Moreover, we discovered a marked downregulation of vitamin D receptor (VDR) during OIS, and a role for the vitamin D/VDR axis regulating the levels of these DNA repair factors during OIS. This study reveals a new functional relationship between the oncogene Ras, the vitamin D/VDR axis and the expression of DNA repair factors, in the context of OIS. The observed deficiencies in DNA repair factors in senescent cells could contribute to the genomic instability that allows senescence bypass and tumorigenesis.

Project description:53BP1 regulates DNA double-strand break (DSB) repair. In functional assays for specific DSB repair pathways, we found that 53BP1 was important in the conservative non-homologous end-joining (C-NHEJ) pathway, and this activity was dependent upon RNF8 and RNF168. We observed that 53BP1 protein was diffusely abundant in nuclei, and upon ionizing radiation, 53BP1 was everywhere degraded except at DNA damage sites. Depletion of RNF8 or RNF168 blocked the degradation of the diffusely localized nuclear 53BP1, and ionizing radiation induced foci (IRIF) did not form. Furthermore, when 53BP1 degradation was inhibited, a subset of 53BP1 was bound to DNA damage sites but bulk, unbound 53BP1 remained in the nucleoplasm, and localization of its downstream effector RIF1 at DSBs was abolished. Our data suggest a novel mechanism for responding to DSB that upon ionizing radiation, 53BP1 was divided into two populations, ensuring functional DSB repair: damage site-bound 53BP1 whose binding signal is known to be generated by RNF8 and RNF168; and unbound bulk 53BP1 whose ensuing degradation is regulated by RNF8 and RNF168.

Project description:Nuclear insulin‑like growth factor 1 receptor (nIGF1R) has been associated with poor overall survival and chemotherapy resistance in various types of cancer; however, the underlying mechanism remains unclear. In the present study, immunoprecipitation‑coupled mass spectrometry was performed in an IGF1R‑overexpressing SW480‑OE colorectal cancer cell line to identify the nIGF1R interactome. Network analysis revealed 197 proteins of interest which were involved in several biological pathways, including RNA processing, DNA double‑strand break (DSB) repair and SUMOylation pathways. Nuclear mitotic apparatus protein (NuMA) was identified as one of nIGF1R's colocalizing partners. Proximity ligation assay (PLA) revealed different levels of p53‑binding protein 1 (53BP1)‑NuMA colocalization between IGF1R‑positive (R+) and IGF1R‑negative (R‑) mouse embryonic fibroblasts following exposure to ionizing radiation (IR). 53BP1 was retained by NuMA in the R‑ cells during IR‑induced DNA damage. By contrast, the level of NuMA‑53BP1 was markedly lower in R+ cells compared with R‑ cells. The present data suggested a regulatory role of nIGF1R in 53BP1‑dependent DSB repair through its interaction with NuMA. Bright‑field PLA analysis on a paraffin‑embedded tissue microarray from patients with colorectal cancer revealed a significant association between increased nuclear colocalizing signals of NuMA‑53BP1 and a shorter overall survival. These results indicate that nIGF1R plays a role in facilitating 53BP1‑dependent DDR by regulating the NuMA‑53BP1 interaction, which in turn might affect the clinical outcome of patients with colorectal cancer.

Project description:The choice between double-strand break (DSB) repair by either homology-directed repair (HDR) or nonhomologous end joining (NHEJ) is tightly regulated. Defects in this regulation can induce genome instability and cancer. 53BP1 is critical for the control of DSB repair, promoting NHEJ, and inhibiting the 5' end resection needed for HDR. Using dysfunctional telomeres and genome-wide DSBs, we identify Rif1 as the main factor used by 53BP1 to impair 5' end resection. Rif1 inhibits resection involving CtIP, BLM, and Exo1; limits accumulation of BRCA1/BARD1 complexes at sites of DNA damage; and defines one of the mechanisms by which 53BP1 causes chromosomal abnormalities in Brca1-deficient cells. These data establish Rif1 as an important contributor to the control of DSB repair by 53BP1.

Project description:The 53BP1-dependent end-joining pathway plays a critical role in double-strand break (DSB) repair. However, the regulators of 53BP1 in chromatin remain incompletely characterized. In this study, we identified HDGFRP3 (hepatoma-derived growth factor related protein 3) as a 53BP1-interacting protein. The HDGFRP3-53BP1 interaction is mediated by the PWWP domain of HDGFRP3 and the Tudor domain of 53BP1. Importantly, we observed that the HDGFRP3-53BP1 complex co-localizes with 53BP1 or γH2AX at sites of DSB and participates in the response to DNA damage repair. Loss of HDGFRP3 impairs classical non-homologous end-joining repair (NHEJ), curtails the accumulation of 53BP1 at DSB sites, and enhances DNA end-resection. Moreover, the HDGFRP3-53BP1 interaction is required for cNHEJ repair, 53BP1 recruitment at DSB sites, and inhibition of DNA end resection. In addition, loss of HDGFRP3 renders BRCA1-deficient cells resistant to PARP inhibitors by facilitating end-resection in BRCA1 deficient cells. We also found that the interaction of HDGFRP3 with methylated H4K20 was dramatically decreased; in contrast, the 53BP1-methylated H4K20 interaction was increased after ionizing radiation, which is likely regulated by protein phosphorylation and dephosphorylation. Taken together, our data reveal a dynamic 53BP1-methylated H4K20-HDGFRP3 complex that regulates 53BP1 recruitment at DSB sites, providing new insights into our understanding of the regulation of 53BP1-mediated DNA repair pathway.