Deciphering the BRCA1 Tumor Suppressor Network

The BRCA1 tumor suppressor protein is a central constituent of several distinct macromolecular protein complexes that execute homology-directed DNA damage repair and cell cycle checkpoints. Recent years have borne witness to an exciting phase of discovery at the basic molecular level for how this network of DNA repair proteins acts to maintain genome stability and suppress cancer. The clinical dividends of this investment are now being realized with the approval of first-in-class BRCA-targeted therapies for ovarian cancer and identification of molecular events that determine responsiveness to these agents. Further delineation of the basic science underlying BRCA network function holds promise to maximally exploit genome instability for hereditary and sporadic cancer therapy.     

Structural basis for recruitment of BRCA2 by PALB2

The breast cancer 2, early onset protein (BRCA2) is central to the repair of DNA damage by homologous recombination. BRCA2 recruits the recombinase RAD51 to sites of damage, regulates its assembly into nucleoprotein filaments and thereby promotes homologous recombination. Localization of BRCA2 to nuclear foci requires its association with the partner and localizer of BRCA2 (PALB2), mutations in which are associated with cancer predisposition, as well as subtype N of Fanconi anaemia. We have determined the structure of the PALB2 carboxy‐terminal β‐propeller domain in complex with a BRCA2 peptide. The structure shows the molecular determinants of this important protein–protein interaction and explains the effects of both cancer‐associated truncating mutants in PALB2 and missense mutations in the amino‐terminal region of BRCA2.     

BRCA1和BRCA2与DNA损伤修复及转录调控

乳腺癌和卵巢癌敏感基因BRCA1和BRCA2与同源重组,DNA损伤修复,胚胎生长,转录调控及遍在蛋白化有关,其中,BRCA1和BRCA2在DNA损伤修复和转录调控中功能的确定,将有助于探讨和阐明两者的肿瘤抑制功能及其机理,作者将综述近年来有关BRCA1和BRCA2在DNA损伤修复和转录调控中功能研究的最新进展。     

APRIN is a cell cycle specific BRCA2-interacting protein required for genome integrity and a predictor of outcome after chemotherapy in breast cancer

Mutations in BRCA2 confer an increased risk of cancer development, at least in part because the BRCA2 protein is required for the maintenance of genomic integrity. Here, we use proteomic profiling to identify APRIN (PDS5B), a cohesion-associated protein, as a BRCA2-associated protein. After exposure of cells to hydroxyurea or aphidicolin, APRIN and other cohesin components associate with BRCA2 in early S-phase. We demonstrate that APRIN expression is required for the normal response to DNA-damaging agents, the nuclear localisation of RAD51 and BRCA2 and efficient homologous recombination. The clinical significance of these findings is indicated by the observation that the BRCA2/APRIN interaction is compromised by BRCA2 missense variants of previously unknown significance and that APRIN expression levels are associated with histological grade in breast cancer and the outcome of breast cancer patients treated with DNA-damaging chemotherapy.     

Centrobin与BRCA2蛋白间相互作用及其细胞定位

为分析乳腺癌易感基因2（breast cancer susceptibility gene 2, BRCA2）蛋白与中心体BRCA2相互作用蛋白（centromal BRCA2 interacting protein, centrobin）间相互作用及其细胞定位的关系,探讨二者功能上的联系,本研究采用哺乳细胞双杂交实验检测体内结合并初步判定BRCA2分子上的结合区域;免疫共沉淀实验进一步验证其体内结合活性,GST-pulldown法检测其体外结合活性,免疫组织化学染色观测BRCA2蛋白的细胞定位及在有丝分裂各期centrobin的细胞定位.结果显示,BRCA2与centrobin间存在体内和体外结合,且BRCA2分子的结合区域主要位于2　393～2　952氨基酸残基处;外源表达BRCA2定位于中心体,在有丝分裂各时相centrobin均定位于中心体. BRCA2与centrobin在体内形成复合物,并存在直接物理结合作用,二者存在细胞空间定位的一致性.该结果为进一步研究BRCA2在中心体复制中的调控作用提供了线索.     

Reduced expression of the BRCA1 gene and increased chromosomal instability in MCF-7 cell line.

Using clonal cell cultures, a significant increase in chromosomal aberrations (aneuplolidy, dicentrics and chromatid breaks) were observed in MCF-7 cells compared with HeLa. BRCA1 expression was lower in MCF-7 cells than in HeLa cells. Since BRCA1 is known to play a role in the maintenance of chromosomal integrity, the increase in chromosomal aberrations in MCF-7 clones suggests that downregulation of BRCA1 expression could be one of the possible mechanisms for increased chromosomal instability in this cell line.     

DNA damage repair is unaffected by mimicked heterozygous levels of BRCA2 in HT-29 cells

Functional loss of both alleles of the breast cancer susceptibility gene, BRCA2, facilitates tumorigenesis. However, the direct effects of BRCA2 heterozygosity remain unclear. Here, BRCA2 heterozygosity was mimicked in HT-29 colon cells by reducing levels of BRCA2 through stable RNA interference. No difference in RAD51 subcellular localization and focus formation was observed between control and mimicked heterozygous cell lines. DNA repair ability, as measured by colony survival following mitomycin C treatment and ultraviolet radiation exposure, was also unaffected by reduced levels of BRCA2. Interestingly, the growth rate of the mimicked BRCA2 heterozygous cell line was significantly lower than that of control cells. Increased expression of p53 in the mimicked heterozygous cells was observed, perhaps in response to BRCA2 deficiency. Levels of p27 were also found to be slightly increased in cells with reduced BRCA2, perhaps contributing to the slower growth rate. Overall, these results suggest that tumors are unlikely to arise directly from BRCA2 heterozygous cells without other genetic events such as loss of the wild-type BRCA2 allele and/or loss of p53 function or other cell cycle inhibitors.     

Focus: 50 Years of DNA Repair: The Yale Symposium Reports: BRCA2: One Small Step for DNA Repair,One Giant Protein Purified

DNA damage, malfunctions in DNA repair, and genomic instability are processes that intersect at the crossroads of carcinogenesis. Underscoring the importance of DNA repair in breast and ovarian tumorigenesis is the familial inherited cancer predisposition gene BRCA2. The role of BRCA2 in DNA double-strand break repair was first revealed based on its interaction with RAD51, a central player in homologous recombination. The RAD51 protein forms a nucleoprotein filament on single-stranded DNA, invades a DNA duplex, and initiates a search for homology. Once a homologous DNA sequence is found, the DNA is used as a template for the high-fidelity repair of the DNA break. Many of the biochemical features that allow BRCA2 to choreograph the activities of RAD51 have been elucidated and include: targeting RAD51 to single-stranded DNA while inhibiting binding to dsDNA, reducing the ATPase activity of RAD51, and facilitating the displacement of the single-strand DNA binding protein, Replication Protein A. These reinforcing activities of BRCA2 culminate in the correct positioning of RAD51 onto a processed DNA double-strand break and initiate its faithful repair by homologous recombination. In this review, I will address current biochemical data concerning the BRCA2 protein and highlight unanswered questions regarding BRCA2 function in homologous recombination and cancer.     

Chromosomal breakage syndromes and the BRCA1 genome surveillance complex

Chromosomal instability can occur when the DNA damage response and repair process fails, resulting in syndromes characterized by growth abnormalities, hematopoietic defects, mutagen sensitivity, and cancer predisposition. Mutations in ATM, NBS1, MRE11, BLM, WRN, and FANCD2 are responsible for ataxia telangiectasia (AT), Nijmegen breakage syndrome, AT-like disorder, Bloom and Werner syndrome, and Fanconi anemia group D2, respectively. This diverse group of disorders is thought to be linked through protein interactions with the breast cancer tumor susceptibility gene product, BRCA1. BRCA1 forms a multi-subunit protein complex referred to as the BRCA1-associated genome surveillance complex (BASC), which includes DNA damage repair proteins such as MSH2-MSH6 and MLH1, as well as ATM, NBS1, MRE11, and BLM. Although still controversial, this finding suggests similarities in the pathogenesis of the human chromosome breakage syndromes and a complementary role for each protein in DNA structure surveillance or damage repair.     

Role of BRCA1 and BRCA2 gene mutations in epithelial ovarian cancer in Indian population: a pilot study

Ovarian cancer is a silent killer as most patients have non-specific symptoms and usually present in advanced stage of the disease. It occurs due to certain genetic alterations and mutations namely founder mutations, 187delAG and 5385insC in BRCA1 and 6174delT in BRCA2 which are associated with specific family histories. These highly penetrant susceptibility genes responsible for approximately half of families containing 2 or more ovarian cancer cases account for less than 40% of the familial excess malignancy risk. The remaining risk may be due to single nucleotide polymorphisms (SNPs) which are single base change in a DNA sequence with usual alternatives of two possible nucleotides at a given position. Preliminary study involving 30 women with histologically proven epithelial ovarian cancer was conducted and their detailed genetic analysis was carried out. Regions of founder mutations on BRCA1 and BRCA2 were amplified and sequenced using primers designed based on 200 bp upstream and downstream regions of the mutation sites. Five sequence variants in BRCA1 were identified of which three novel sequence variants were found in 23 patients while in BRCA2, one novel sequence variant was found. The three founder mutations 187delAG, 5385insC in BRCA1 and 6174delT in BRCA2 were not seen in any of the subjects.     

Repair and Reconstruction of Telomeric and Subtelomeric Regions and Genesis of New Telomeres: Implications for Chromosome Evolution

DNA damage repair within telomeres are suppressed to maintain the integrity of linear chromosomes, but the accidental activation of repairs can lead to genome instability. This review develops the concept that mechanisms to repair DNA damage in telomeres contribute to genetic variability and karyotype evolution, rather than catastrophe. Spontaneous breaks in telomeres can be repaired by telomerase, but in some cases DNA repair pathways are activated, and can cause chromosomal rearrangements or fusions. The resultant changes can also affect subtelomeric regions that are adjacent to telomeres. Subtelomeres are actively involved in such chromosomal changes, and are therefore the most variable regions in the genome. The case of Caenorhabditis elegans in the context of changes of subtelomeric structures revealed by long-read sequencing is also discussed. Theoretical and methodological issues covered in this review will help to explore the mechanism of chromosome evolution by reconstruction of chromosomal ends in nature.     

RADX prevents genome instability by confining replication fork reversal to stalled forks

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Chromosomal instability in the lymphocytes of breast cancer patients

Genomic instability in the tumor tissue has been correlated with tumor progression. In the present study, chromosomal aberrations (CAs) in peripheral blood lymphocytes (PBLs) of breast tumor patients were studied to assess whether chromosomal instability (CIN) in PBLs correlates with aggressiveness of breast tumor (i.e., disease stage) and has any prognostic utility. Cultured blood lymphocyte metaphases were scored for aberrations in 31 breast cancer patients and 20 healthy age and sex-matched controls. A variety of CAs, including aneuploidy, polyploidy, terminal deletions, acentric fragments, double minutes, chromatid separations, ring chromosome, marker chromosome, chromatid gaps, and breaks were seen in PBLs of the patients. The CAs in patients were higher than in controls. A comparison of the frequency of metaphases with aberrations by grouping the patients according to the stage of advancement of disease did not reveal any consistent pattern of variation in lymphocytic CIN. Neither was any specific chromosomal abnormality found to be associated with the stage of cancer. This might be indicative of the fact that cancer patients have constitutional CIN, which predisposes them to the disease, and this inherent difference in the level of genomic instability might play a role in disease progression and response to treatment.     

Identification of Rad51 regulation by BRCA2 using Caenorhabditis elegans BRCA2 and bimolecular fluorescence complementation analysis

BRCA2 is involved in double-stranded DNA break repair by binding and regulating Rad51-mediated homologous recombination. Insights as to how BRCA2 regulates Rad51-mediated DNA repair arose from in vitro biochemical studies on fragments of BRCA2. However, the large 400-kDa BRCA2 protein has hampered our ability to understand the entire process by which full-length BRCA2 regulates Rad51. Here, we show that CeBRC-2, which is only one tenth the size of mammalian BRCA2, complemented BRCA2-deficiency in Rad51 regulation. CeBRC-2 was able to bind to mammalian Rad51 (mRad51) and form distinct nuclear foci when they interacted. In our bimolecular fluorescence complementation analysis (BiFC), we show that the strength of the interaction between CeBRC-2 and mRad51 increased markedly after DNA damage. The BRC motif of CeBRC-2 was responsible for binding mRad51, but without the OB fold, the complex was unable to target damaged DNA. When CeBRC-2 was introduced into BRCA2-deficient cells, it restored Rad51 foci after DNA damage. Our study suggests a mode of action for BRCA2 with regard to DNA repair.     

Reproductive factors and breast cancer risk among BRCA1 or BRCA2 mutation carriers: Results from ten studies

Although reproductive factors are among the most well-established risk factors for breast cancer in the general population, it is still a matter for debate whether these factors act as risk modifiers among BRCA1 or BRCA2 mutation carriers. This meta-analysis is the first to be performed to determine the relationship between reproductive factors and breast cancer risk among BRCA1 and BRCA2 mutation carriers. We searched the PubMed database up to February 2013. A total of ten studies met the inclusion criteria. The results showed that the reproductive factors may be associated with breast cancer risk only among BRCA1 mutation carriers. No association was found between parity and breast cancer risk. Compared with women at the youngest age in the first-birth category, women in the oldest age category were at a 38% lower risk of breast cancer (RR = 0.62, 95%CI = 0.45–0.85). Breastfeeding for at least 1 or 2 years was associated with a 37% reduction in breast cancer risk (RR = 0.63, 95%CI = 0.46–0.86). Women at the oldest age in the menarche category were at a 34% lower risk of breast cancer (RR = 0.66, 95%CI = 0.53–0.81) than women in the youngest age category. However, none of the reproductive factors were associated with breast cancer risk among BRCA2 mutation carriers. In conclusion, late age at first birth, breastfeeding, and late age at menarche protect against breast cancer in BRCA1 mutation carriers only. Further studies are needed to explore the mechanisms.     

RIPK1 and Caspase-8 Ensure Chromosome Stability Independently of Their Role in Cell Death and Inflammation

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NCAPH Stabilizes GEN1 in Chromatin to Resolve Ultra-Fine DNA Bridges and Maintain Chromosome Stability

Repairing damaged DNA and removing all physical connections between sister chromosomes is important to ensure proper chromosomal segregation by contributing to chromosomal stability. Here, we show that the depletion of non-SMC condensin I complex subunit H (NCAPH) exacerbates chromosome segregation errors and cytokinesis failure owing to sister-chromatid intertwinement, which is distinct from the ultra-fine DNA bridges induced by DNA inter-strand crosslinks (DNA-ICLs). Importantly, we identified an interaction between NCAPH and GEN1 in the chromatin involving binding at the N-terminus of NCAPH. DNA-ICL activation, using ICL-inducing agents, increased the expression and interaction between NCAPH and GEN1 in the soluble nuclear and chromatin, indicating that the NCAPH–GEN1 interaction participates in repairing DNA damage. Moreover, NCAPH stabilizes GEN1 within chromatin at the G2/M-phase and is associated with DNA-ICL-induced damage repair. Therefore, NCAPH resolves DNA-ICL-induced ultra-fine DNA bridges by stabilizing GEN1 and ensures proper chromosome separation and chromosome structural stability.     

Mitotic DNA synthesis is caused by transcription-replication conflicts in BRCA2-deficient cells

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