CHD1 loss sensitizes prostate cancer to DNA damaging therapy by promoting error-prone double-strand break repair

BackgroundDeletion of the chromatin remodeler chromodomain helicase DNA-binding protein 1 (CHD1) is a common genomic alteration found in human prostate cancers (PCas). CHD1 loss represents a distinct PCa subtype characterized by SPOP mutation and higher genomic instability. However, the role of CHD1 in PCa development in vivo and its clinical utility remain unclear.Patients and methodsTo study the role of CHD1 in PCa development and its loss in clinical management, we generated a genetically engineered mouse model with prostate-specific deletion of murine Chd1 as well as isogenic CHD1 wild-type and homozygous deleted human benign and PCa lines. We also developed patient-derived organoid cultures and screened patients with metastatic PCa for CHD1 loss.ResultsWe demonstrate that CHD1 loss sensitizes cells to DNA damage and causes a synthetic lethal response to DNA damaging therapy in vitro, in vivo, ex vivo, in patient-derived organoid cultures and in a patient with metastatic PCa. Mechanistically, CHD1 regulates 53BP1 stability and CHD1 loss leads to decreased error-free homologous recombination (HR) repair, which is compensated by increased error-prone non-homologous end joining (NHEJ) repair for DNA double-strand break (DSB) repair.ConclusionsOur study provides the first in vivo and in patient evidence supporting the role of CHD1 in DSB repair and in response to DNA damaging therapy. We uncover mechanistic insights that CHD1 modulates the choice between HR and NHEJ DSB repair and suggest that CHD1 loss may contribute to the genomic instability seen in this subset of PCas.     

Polymorphisms in DNA double-strand break repair genes and skin cancer risk

UV can cause a wide range of DNA lesions. UVA-induced oxidative DNA damage and blocked DNA replication by UVB-induced photoproducts can lead to double-strand breaks (DSBs). We selected 11 haplotype-tagging single nucleotide polymorphisms in three DSB repair genes XRCC2, XRCC3, and LigaseIV and evaluated their associations with skin cancer risk in a nested case-control study within the Nurses' Health Study [219 melanoma, 286 squamous cell carcinoma (SCC), 300 basal cell carcinoma (BCC), and 873 controls]. We observed that the XRCC3 18085T (241Met) allele and its associated haplotype were significantly inversely associated with the risks of SCC and BCC, whereas the XRCC3 4552C allele along with its associated haplotype and the XRCC2 30833A allele were significantly associated with increased BCC risk. The LigaseIV 4044T and 4062T alleles were associated with decreased BCC risk; two of four haplotypes were significantly associated with altered BCC risk. A trend toward decreased risk of nonmelanoma skin cancer was found in those harboring a greater number of putative low risk alleles (P for trend, 0.05 for SCC, <0.0001 for BCC). The main effects of these genotypes were essentially null for melanoma risk. This study provides evidence to suggest the role of the DSB repair pathway in skin cancer development, especially for BCC.     

DNA双链断裂修复蛋白表达水平与肿瘤细胞放射敏感性的关系研究

目的：检测肿瘤细胞株中DNA双链断裂修复蛋白（Ku80、DNA-PKcs和ATM）的表达水平和放射敏感性参数,探讨3个蛋白预示肿瘤细胞放射敏感性的价值。方法：培养4株人宫颈癌细胞HeLa、SiHa、C33A和Caski,3株人乳腺癌细胞MCF-7、MDA-MB-231和MDA-MB-453,及1株人肺癌细胞A549,Western blot检测这8株细胞中Ku80、DNA-PKcs和ATM蛋白的表达水平;流式细胞仪检测X线（10 Gy,6 MV）照射48 h后的凋亡率;克隆形成实验检测SF2（surviving fraction at 2 Gy）值和α、β值;Pearson线性相关分析蛋白表达水平与照射后凋亡率、SF2值和α/β比值的相关性。结果：3种蛋白在同一株细胞中的表达及同一蛋白在不同细胞株的表达均存在明显差异;DNA-PKcs的表达水平与SF2之间存在正相关关系（r=0.723,P=0.043）;Ku80和ATM的表达与SF2值间无明显相关关系（P〉0.05）。3种蛋白与凋亡率和α/β比值均无相关性（均P〉0.05）。结论：DNA-PKcs蛋白表达越高,细胞对放射线越抵抗,其表达水平可能成为指示肿瘤细胞放射敏感性的指标。     

Expression of DNA double-strand break repair proteins ATM and BRCA1 predicts survival in colorectal cancer.

PURPOSE: The double-strand break (DSB) is the major DNA lesion leading to chromosomal aberrations and faithful repair is crucial for maintaining genomic instability. Very little is known about the expression of DNA DSB repair proteins in colorectal cancer. To address this issue, we examined the expression pattern of DSB repair key proteins ATM, BRCA1, BRCA2, Ku70, and Ku80 and their putative role in patients survival in a large series of colorectal cancer. EXPERIMENTAL DESIGN: 342 sporadic colorectal cancer were subjected to immunohistochemistry by using specific antibodies for the various proteins investigated. Staining results were compared with clinicopathologic data, patient survival, as well as expression of mismatch repair proteins MLH1 and MSH2. RESULTS: The expression pattern of both ATM and BRCA1 predicted survival in all colorectal cancer patients as well as in the small subgroup of patients that received adjuvant therapy. Low expression of ATM and BRCA1 was associated with loss of MLH1 or MSH2 expression. CONCLUSIONS: This is the first study to show a relationship between the expression of DNA DSB repair proteins ATM and BRCA1 and survival in colorectal cancer patients. Studies in tumors from large randomized trials are now necessary to validate our pilot data and establish the clinical usefulness of the immunohistochemical assay in predicting response to a particular adjuvant therapy regimen. Furthermore, our results indicate a possible link between expression of DNA mismatch repair and DNA DSB repair proteins in sporadic colorectal cancer, which warrants further investigation.     

Distinct functions of BRCA1 and BRCA2 in double-strand break repair

Individuals carrying BRCA mutations are predisposed to breast cancer. The BRCA1 and BRCA2 proteins are required for homologous recombination and DNA break repair, leading to the suggestion that they act in concert. However, direct evidence of a stable BRCA1/BRCA2 complex has not been demonstrated. Rather, the two proteins have been found as constituents of discrete, but perhaps nonexclusive complexes that are critical for repair. We discuss the interaction of BRCA1 with the BACH1 and BARD1 proteins, and suggest that the pleiotropic nature of mutations in BRCA1 may be associated with defects in protein–protein interactions. In contrast, the role of BRCA2 in DNA repair may be more defined by its direct interaction with the RAD51 recombinase.     

Distinct functions of BRCA1 and BRCA2 in double-strand break repair

Individuals carrying BRCA mutations are predisposed to breast cancer. The BRCA1 and BRCA2 proteins are required for homologous recombination and DNA break repair, leading to the suggestion that they act in concert. However, direct evidence of a stable BRCA1/BRCA2 complex has not been demonstrated. Rather, the two proteins have been found as constituents of discrete, but perhaps nonexclusive complexes that are critical for repair. We discuss the interaction of BRCA1 with the BACH1 and BARD1 proteins, and suggest that the pleiotropic nature of mutations in BRCA1 may be associated with defects in protein--protein interactions. In contrast, the role of BRCA2 in DNA repair may be more defined by its direct interaction with the RAD51 recombinase.     

The proteomic investigation reveals interaction of mdig protein with the machinery of DNA double-strand break repair

To investigate how mineral dust-induced gene (mdig, also named as mina53, MINA, or NO52) promotes carcinogenesis through inducing active chromatin, we performed proteomics analyses for the interacting proteins that were co-immunoprecipitated by anti-mdig antibody from either the lung cancer cell line A549 cells or the human bronchial epithelial cell line BEAS-2B cells. On SDS-PAGE gels, three to five unique protein bands were consistently observed in the complexes pulled-down by mdig antibody, but not the control IgG. In addition to the mdig protein, several DNA repair or chromatin binding proteins, including XRCC5, XRCC6, RBBP4, CBX8, PRMT5, and TDRD, were identified in the complexes by the proteomics analyses using both Orbitrap Fusion and Orbitrap XL nanoESI-MS/MS in four independent experiments. The interaction of mdig with some of these proteins was further validated by co-immunoprecipitation using antibodies against mdig and its partner proteins, respectively. These data, thus, provide evidence suggesting that mdig accomplishes its functions on chromatin, DNA repair and cell growth through interacting with the partner proteins.     

DNA双链断裂修复基因XRCC4多态性与肺癌易感性的关系

目的:探讨DNA双链断裂修复基因X-射线修复交叉互补4(X-ray repair cross-complementing 4, XRCC4)基因单核甘酸多态性(single nucleotide polymorphism, SNP)与肺癌发生风险的关系.方法:采用病例-对照研究的方法,应用聚合酶链反应-限制性片段长度多态性(polymerase chain reaction-restriction fragment length polymorphism, PCR-RFLP)技术和TaqMan探针基因分型技术对781例肺癌患者和781健康志愿者(作为对照)进行XRCC4 rs6869366、rs3734091和rs1056503多态性的检测;结合PCR和定点突变技术,分别构建含有XRCC4基因启动子rs6869366位点不同等位基因的重组质粒,以双荧光素酶报告系统检测SNP位点碱基突变对启动子活性的影响.结果:XRCC4 rs6869366位点携带G等位基因的基因型(T/G+G/G)可显著增加肺癌的患病风险[比值比(odds ratio, OR)=1.607, 95%可信区间(confidence interval,CI): 1.138~2.270];rs6869366与rs3734091存在连锁不平衡,携带由其构建的单体型GC或单体型对TC/GC者患肺癌的风险增加(OR=1.993,95%CI:1.194~3.329;OR=2.013,95%CI:1.174~3.452);含rs6869366不同等位基因的启动子转录活性差异无统计学意义.结论:XRCC4 rs6869366位点多态性与肺癌的易感性有关,其影响机制还需进一步研究.     

Rb inactivation leads to E2F1-mediated DNA double-strand break accumulation

Although it is unclear which cellular factor(s) is responsible for the genetic instability associated with initiating and sustaining cell transformation, it is known that many cancers have mutations that inactivate the Rb-mediated proliferation pathway. We show here that pRb inactivation and the resultant deregulation of one E2F family member, E2F1, leads to DNA double-strand break (DSB) accumulation in normal diploid human cells. These DSBs occur independent of Atm, p53, caspases, reactive oxygen species, and apoptosis. Moreover, E2F1 does not contribute to c-Myc-associated DSBs, indicating that the DSBs associated with these oncoproteins arise through distinct pathways. We also find E2F1-associated DSBs in an Rb mutated cancer cell line in the absence of an exogenous DSB stimulus. These basal, E2F1-associated DSBs are not observed in a p16(ink4a) inactivated cancer cell line that retains functional pRb, unless pRb is depleted. Thus, Rb status is key to regulating both the proliferation promoting functions associated with E2F and for preventing DNA damage accumulation if E2F1 becomes deregulated. Taken together, these data suggest that loss of Rb creates strong selective pressure, via DSB accumulation, for inactivating p53 mutations and that E2F1 contributes to the genetic instability associated with transformation and tumorigenesis.     

Variants in DNA double-strand break repair genes and risk of familial breast cancer in a South American population

The double-strand break (DSB) DNA repair pathway has been implicated in breast cancer (BC). RAD51 and its paralogs XRCC3 and RAD51D play an important role in the repair of DSB through homologous recombination (HR). Some polymorphisms including XRCC3-Thr241Met, RAD51-135G>C, and RAD51D-E233G have been found to confer increased BC susceptibility. In order to detect novel mutations that may contribute to BC susceptibility, 150 patients belonging to 150 Chilean BRCA1/2-negative families were screened for mutations in XRCC3. No mutations were detected in the XRCC3 gene. In addition, using a case–control design we studied the XRCC3-Thr241Met, and RAD51D-E233G polymorphisms in 267 BC cases and 500 controls to evaluate their possible association with BC susceptibility. The XRCC3 Met/Met genotype was associated with an increased BC risk (P = 0.003, OR = 2.44 [95%CI 1.34–4.43]). We did not find an association between E233G polymorphism and BC risk. We also analyzed the effect of combined genotypes among RAD51-135G>C, Thr241Met, and E233G polymorphisms on BC risk. No interaction was observed between Thr241Met and 135G>C. The combined genotype Thr/Met–E/G was associated with an increased BC risk among women who (a) have a family history of BC, (b) are BRCA1/2-negative, and (c) were <50 years at onset (n = 195) (P = 0.037, OR = 10.5 [95%CI 1.16–94.5]). Our results suggested that the variability of the DNA HR repair genes XRCC3 and RAD51D may play a role in BC risk, but this role may be underlined by a mutual interaction between these genes. These findings should be confirmed in other populations.     

Polymorphisms in DNA double-strand break repair genes and breast cancer risk in the Nurses' Health Study

Genetic polymorphisms in double-strand break repair genes may influence DNA repair capacity and, in turn, confer predisposition to breast cancer. We prospectively assessed the associations of candidate polymorphisms G31479A (R188H) in XRCC2, A4541G (5'-UTR), A17893G (IVS5-14) and C18067T (T241 M) in XRCC3, and C299T (5'-UTR) and T1977C (D501D) in Ligase IV with breast cancer risk in a nested case-control study within the Nurses' Health Study (incident cases, n=1004; controls, n=1385). We observed no overall associations of these six genotypes with breast cancer risk. Four common haplotypes in XRCC3 accounted for 99% of the chromosomes of the present study population. We observed that Ligase IV 1977C carriers were at increased breast cancer risk if they had a first degree family history of breast cancer (test for interaction, P=0.01). We observed that the XRCC2 R188H polymorphism modified the association of plasma alpha-carotene level and breast cancer risk (test for ordinal interaction, P=0.03); the significantly decreased risk seen overall for women in the highest quartile of plasma alpha-carotene was only present among 188H non-carriers (the top quartile versus the bottom quartile; multivariate odds ratio, 0.55; 95% confidence interval, 0.40-0.75). No significant interactions were seen between any of these polymorphisms and duration or dose of cigarette smoking. The gene-environment interaction data suggest that the subtle effects of some of these variants on breast cancer risk may be magnified in the presence of certain exposures.     

Fidelity of DNA double-strand break repair in heterozygous cell lines harbouring BRCA1 missense mutations

Germ-line mutations of the BRCA1 and BRCA2 genes, when they lead to a truncated protein, confer a high risk of breast and ovarian cancer. However, the role of BRCA1 missense mutations in cancer predisposition is unclear. Functional assays may be very helpful to more clearly define the biological effect of these mutations, and could therefore be useful in clinical practice. A recent study using a Host Cell End-Joining assay showed that a truncating mutation results in impaired fidelity of DSB repair by DNA end-joining. In the present study, we examined the fidelity of DSB repair in four lymphoblastoid cell lines with BRCA1 missense mutations. The fidelity of DNA end-joining was impaired in the four cell lines studied compared to the normal control cell line. The fidelity of end-joining was similar to that of a truncated mutation control cell line for one cell line and slightly higher for the other cell lines.     

Identification of two novel BRCA1-partner genes in the DNA double-strand break repair pathway

M1775R and A1789T are two missense variants located within the BRCT domains of BRCA1 gene. The M1775R is a known deleterious variant, while the A1789T is an unclassified variant that has been analyzed and classified as probably deleterious for the first time by our group. In a previous study, we described the expression profile of HeLa G1 cells transfected with the two variants and we found that they altered molecular mechanisms critical for cell proliferation and genome integrity. Considering that the mutations in the BRCA1 C terminus (BRCT) domains are associated to a phenotype with an altered ability in the DNA double-strand break repair, we chose three of the genes previously identified, EEF1E1, MRE11A, and OBFC2B, to be tested for an homologous recombination (HR) in vitro assay. For our purpose, we performed a gene expression knockdown by siRNA transfection in HeLa cells, containing an integrated recombination substrate (hprtDRGFP), for each of the target genes included BRCA1. The knockdown of BRCA1, OBFC2B, MRE11A, and EEF1E1 reduces the HR rate, respectively, of 97.6, 28.6, 41.8, and 42.3 % compared to cells transfected with a scrambled negative control duplex and all these differences are statistically significant (P < 0.05; Kruskal–Wallis test). Finally, we analyzed the effect of target gene depletion both on HR that on cell survival after DNA-damage induction by ionizing radiation. The clonogenic assay showed that the down-regulation of the target genes reduced the cell survival, but the effect on the HR, is not evident. Only the BRCA1-siRNA confirmed the inhibition effect on HR. Overall these results confirmed the involvement of MRE11A in the HR pathway and identified two new genes, OBFC2B and EEF1E1, which according to these data and the knowledge obtained from literature, might be involved in BRCA1-pathway.     

DNA double-strand break repair,DNA-PK,and DNA ligases in two human squamous carcinoma cell lines with different radiosensitivity

Purpose: Variation in sensitivity to radiotherapy among tumors has been related to the capacity of cells to repair radiation-induced DNA double-strand breaks (DSBs). DNA-dependent protein kinase (DNA-PK) and DNA ligases may affect DNA dsb rejoining. This study was performed to compare rate of rejoining of radiation-induced DSBs, DNA-PK, and DNA ligase activities in two human squamous carcinoma cell lines with different sensitivity to ionizing radiation.Methods and Materials: Cell survival of two human squamous carcinoma cell lines, UM-SCC-1 and UM-SCC-14A, was determined by an in vitro clonogenic assay. DSB rejoining was studied using pulsed field gel electrophoresis (PFGE). DNA-PK activity was determined using BIOTRAK DNA-PK enzyme assay system (Amersham). DNA ligase activity in crude cell extracts was measured using [5′-³³P] Poly (dA)·(oligo (dT) as a substrate. Proteolytic degradation of proteins was analyzed by means of Western blotting.Results: Applying the commonly used linear-quadratic equation to describe cell survival, S = e^-αD-βD2, the two cell lines roughly have the same α value (∼0.40 Gy^-1) whereas the β value was considerably higher in UM-SCC-14A (0.067 Gy^-2 ± 0.007 Gy^-2 [SEM]) as compared to UM-SCC-1 (0.013 Gy^-2 ± 0.004 Gy^-2 [SEM]). Furthermore, UM-SCC-1 was more proficient in rejoining of X-ray-induced DSBs as compared to UM-SCC-14A as quantified by PFGE. The constitutive level of DNA-PK activity was 1.6 times higher in UM-SCC-1 as compared to UM-SCC-14A (p < 0.05). The constitutive level of DNA ligase activity was similar in the two cell lines.Conclusions: The results suggest that the proficiency in rejoining of DSBs is associated with DNA-PK activity but not with total DNA ligase activity.     

TNKS1BP1 functions in DNA double-strand break repair though facilitating DNA-PKcs autophosphorylation dependent on PARP-1

TNKS1BP1 was originally identified as an interaction protein of tankyrase 1, which belongs to the poly(ADP-ribose) polymerase (PARP) superfamily. PARP members play important roles for example in DNA repair, telomere stability and mitosis regulation. Although the TNKS1BP1 protein was considered to be a poly(ADP-ribosyl)ation acceptor of tankyrase 1, its function is still unknown. Here we firstly identified that TNKS1BP1 was up-regulated by ionizing radiation (IR) and the depletion of TNKS1BP1 significantly sensitized cancer cells to IR. Neutral comet assay, pulsed-field gel electrophoresis, and γH2AX foci analysis indicated that TNKS1BP1 is required for the efficient repair of DNA double-strand breaks (DSB). The TNKS1BP1 protein was demonstrated to interact with DNA-dependent protein kinase (DNA-PKcs) and poly(ADP-ribose) polymerase 1 (PARP-1), by co-immunoprecipitation analysis. Moreover, TNKS1BP1 was shown to promote the association of PARP-1 and DNA-PKcs. Overexpression of TNKS1BP1 induced the autophosphorylation of DNA-PKcs/Ser2056 in a PARP-1 dependent manner, which contributed to an increased capability of DNA DSB repair. Inhibition of PARP-1 blocked the TNKS1BP1-mediated DNA-PKcs autophosphorylation and attenuated the PARylation of DNA-PKcs. TNKS1BP1 is a newly described component of the DNA DSB repair machinery, which provides much more mechanistic evidence for the rationale of developing effective anticancer measures by targeting PARP-1 and DNA-PKcs.     

Polymorphisms in genes involved in DNA double-strand break repair pathway and susceptibility to benzene-induced hematotoxicity

Benzene is a recognized hematotoxicant and carcinogen that produces genotoxic damage. DNA double-strand breaks (DSB) are one of the most severe DNA lesions caused directly and indirectly by benzene metabolites. DSB may lead to chromosome aberrations, apoptosis and hematopoietic progenitor cell suppression. We hypothesized that genetic polymorphisms in genes involved in DNA DSB repair may modify benzene-induced hematotoxicity. We analyzed one or more single nucleotide polymorphisms (SNPs) in each of seven candidate genes (WRN, TP53, NBS1, BRCA1, BRCA2, XRCC3 and XRCC4) in a study of 250 workers exposed to benzene and 140 controls in China. Four SNPs in WRN (Ex4 -16 G > A, Ex6 +9 C > T, Ex20 -88 G > T and Ex26 -12 T > G), one SNP in TP53 (Ex4 +119 C > G) and one SNP in BRCA2 (Ex11 +1487 A > G) were associated with a statistically significant decrease in total white blood cell (WBC) counts among exposed workers. The SNPs in WRN and TP53 remained significant after accounting for multiple comparisons. One or more SNPs in WRN had broad effects on WBC subtypes, with significantly decreased granulocyte, total lymphocyte, CD4(+)-T cell, CD8(+)-T cell and monocyte counts. Haplotypes of WRN were associated with decreased WBC counts among benzene-exposed subjects. Likewise, subjects with TP53 Ex4 +119 C > G variant had reduced granulocyte, CD4(+)-T cell and B cell counts. The effect of BRCA2 Ex11 +1487 A > G polymorphism was limited to granulocytes. These results suggest that genetic polymorphisms in WRN, TP53 and BRCA2 that maintain genomic stability impact benzene-induced hematotoxicity.     

Histone H2AX sensitizes glioma cells to genotoxic stimuli by recruiting DNA double-strand break repair proteins

Glioblastoma is a life-threatening tumor in the human brain despite the fact that radio-chemotherapy inducing DNA damage has been improved in the last decade. Various studies focusing on the enhancement of the susceptibility of glioblastoma cells to DNA damage have been reported, which are aimed at more efficient treatment for the tumor. In this study, we show that radioresistant T98G glioblastoma cells can develop sensitivity to DNA damage induced by irradiation and etoposide as a result of the introduction of a DNA repair-associated histone, H2AX. Interestingly, when H2AX-transformed T98G cells were irradiated, Brca1 and Nbs1 were readily recruited in DNA double-strand break (DSB) foci and showed the G2/M-phase arrest of the cell cycle. Moreover, up-regulation of Brca1 was observed in H2AX-T98G cells after exposure to irradiation. Together with the evidence that H2AX transfection does not affect growth activities of non-tumor cells under genotoxic stimuli, this suggests that H2AX gene transfer would provide a new modality for radio-chemotherapy for glioblastomas, probably through overcoming the instability of the genome, and that Brca1 and Nbs1 might be crucial in this methodology.