The Role of BRCA1 in DNA Double-strand Break Repair

Dever, Seth

29 April 2009

Mutations in the breast cancer susceptibility 1 (BRCA1) gene are linked to breast as well as ovarian cancers. However, most cancer-causing mutations within the BRCA1 gene have been found in the N’ and C’ terminal regions of the BRCA1 protein, both believed to be important for DNA double-strand break (DSB) repair. The BRCA1 C’ terminal (BRCT) repeats have been implicated in phospho-serine protein binding whereas the N’ terminal RING domain interacts with the BARD1 protein to form a hetero-dimeric complex with E3 ubiquitin ligase activity. The BRCA1 BRCT domain binds CtIP, BACH1, and RAP80, all of which have been directly implicated in homologous recombination repair (HRR). Lysine 1702 (K1702) of BRCA1 resides within the phospho-serine binding pocket of the first BRCT repeat of BRCA1. To determine the effect of manipulating the ability of BRCA1 to bind CtIP and other phospho-proteins binding to the BRCA1 BRCT domain on DSB repair, and specifically HRR, we introduced a K1702M mutation into BRCA1 known to impair BRCT binding to a pSer-X-X-Phe peptide representing BACH1. Surprisingly, instead of impairing HRR, we found that BRCA1 K1702M resulted in hyper-recombination with > 3-fold higher levels of HRR compared to wild-type BRCA1 using an HRR assay based on GFP expression in BRCA1-defective HCC1937 cells. This hyper-recombinogenic phenotype coincided with cell-cycle arrest in S/G2 suggesting that the potential lack of binding of critical proteins to the BRCA1 BRCT domain results in abnormal HRR by priming cells to undergo more HRR which is enhanced during the S and G2 phases of the cell-cycle. In line with the increased HRR seen with the HRR/GFP assay, HCC1937 cells expressing BRCA1 K1702M showed increased levels of RAD51 foci and nuclear staining suggesting that HRR was highly elevated. Interestingly, the hyper-recombinogenic phenotype of BRCA1 K1702M could be reduced to normal levels with a second mutation (I26A) in BRCA1 that affects BRCA1 and CtIP ubiquitination. These results reveal a hierarchal regulation of HRR with ubiquitination having a dominate role in DSB repair by BRCA1 and suggests that targeted disruption of BRCT-CtIP binding increases HRR that is in turn controlled by ubiquitination. In addition, we provide evidence that BRCA1 serine 1387 phosphorylation within the SQ cluster region of BRCA1 is involved in the cell survival and DNA damage response to IR. The BRCA1 S1387A mutant only partially increased the radiosurvival of HCC1937 cells compared to cells expressing wild-type BRCA1 and immunocytochemical analysis revealed wild-type BRCA1 was located in the nucleus whereas the S1387A mutant was cytoplasmic in response to IR. We also show that BRCA1 SQ cluster serine phosphorylation in addition to serine 1387 is involved in HRR. Altogether, these findings reveal the importance of various regions of BRCA1 in DSB repair and may lead to multiple strategies of modulating BRCA1 function in response to DNA damage.

BRCA1

Homologous recombination

Life Sciences

Identification of MMS22 as a regulator of DNA repair

Duro, Eris

January 2010

Obstacles such as DNA damage can block the progression of DNA replication forks. This is a major source of genome instability that can lead to cell transformation or death. The budding yeast MMS1 and MMS22 genes were identified in a screen for mutants that were hypersensitive to DNA alkylation that blocks replisome progression. I set out to investigate the cellular roles of these genes and found that cells lacking MMS1 or MMS22 are hypersensitive to a wide variety of genotoxins that stall or block replication forks, and are severely defective in their ability to recover from DNA alkylation damage. Homologous recombination (HR) is an important mechanism for the rescue of stalled or blocked replication forks and for the repair of double-strand breaks (DSBs). Strikingly, MMS1 and MMS22 are required for HR induced by replication stress but not by DSBs, and the underlying mechanisms were explored.I next identified the uncharacterized protein C6ORF167 (MMS22L) as a putative human Mms22 orthologue. MMS22L interacts with NF?BIL2/TONSL, the histone chaperone ASF1 and subunits of the MCM replicative helicase. MMS22L colocalizes with TONSL at perturbed replication forks and at sites of DNA damage. MMS22L and TONSL are important for the repair of collapsed replication forks as depletion of MMS22L or TONSL from human cells causes DNA damage during S–phase and hypersensitivity to agents that cause fork collapse. These defects are consistent with the observations that MMS22L and TONSL are required for the efficient loading of the RAD51 recombinase onto resected DNA ends and for efficient HR. These data indicate that MMS22L and TONSL are novel regulators of genome stability that enable efficient HR.

572.6

EXAMINING THE ROLE OF THE XAB2 PROTEIN IN HOMOLOGOUS RECOMBINATION

Neherin, Kashfia

01 June 2015

DNA double strand break (DSB) repair is critical to maintain genomic integrity and cell viability. DSBs can occur during the course of cell cycle during replication or transcription, or by exogenous agents such as chemicals or ionizing radiation. For my thesis, I studied homologous recombination (HR), which has two sub-pathways: Homology Directed Repair (HDR) and Single Strand Annealing (SSA). HDR involves strand invasion of a homologous template to prime DNA synthesis; SSA involves annealing of homologous segments flanking a DSB. Background data showed that depletion of XAB2 protein by RNA interference reduced both HDR and SSA events. XAB2 protein contains 15 tetratricopeptide repeat (TPR) motifs, which likely enable protein-protein interactions. While XAB2 is speculated to have a role in transcription coupled repair and pre-mRNA splicing, its role in HR pathway is uncertain. The overall hypothesis for my thesis is that XAB2 mediates a specific step of HR (5’-3’ end resection), and the TPR motifs present in XAB2 enable the protein to function in a complex during HR. By using an end resection assay and cell biology analysis, I found that XAB2 is essential for 5’ – 3’ end resection, an intermediate step common to both HDR and SSA pathways. With a functional complementation assay I developed, I have shown that specific TPR regions are critical for XAB2 functions in HR. Overall, my research demonstrates that XAB2 protein has a key role in the 5’-3’ end resection step of HR, and its function in HR requires specific sets of its TPR regions.

Homologous recombination

XAB2

Double strand break

DNA damage

Molecular Genetics

Topological Data Analysis of Properties of Four-Regular Rigid Vertex Graphs

Conine, Grant Mcneil

24 June 2014

Homologous DNA recombination and rearrangement has been modeled with a class of four-regular rigid vertex graphs called assembly graphs which can also be represented by double occurrence words. Various invariants have been suggested for these graphs, some based on the structure of the graphs, and some biologically motivated. In this thesis we use a novel method of data analysis based on a technique known as partial-clustering analysis and an algorithm known as Mapper to examine the relationships between these invariants. We introduce some of the basic machinery of topological data analysis, including the construction of simplicial complexes on a data set, clustering analysis, and the workings of the Mapper algorithm. We define assembly graphs and three specific invariants of these graphs: assembly number, nesting index, and genus range. We apply Mapper to the set of all assembly graphs up to 6 vertices and compare relationships between these three properties. We make several observations based upon the results of the analysis we obtained. We conclude with some suggestions for further research based upon our findings.

Assembly Graph

Homologous Recombination

Mapper

Topological Data Analysis

Mathematics

Microbiology

A Genome-Wide Study of Homologous Recombination in Mammalian Cells Identifies RBMX, a Novel Component of the DNA Damage Response

Adamson, Brittany Susan

20 March 2013

Repair of DNA double-strand breaks is critical to the maintenance of genomic stability, and failure to repair these DNA lesions can cause loss of chromosome telomeric regions, complex translocations, or cell death. In humans this can lead to severe developmental abnormalities and cancer. A central pathway for double-strand break repair is homologous recombination (HR), a mechanism that operates during the S and G2 phases of the cell cycle and primarily utilizes the replicated sister chromatid as a template for repair. Most knowledge of HR is derived from work carried out in prokaryotic and eukaryotic model organisms. To probe the HR pathway in human cells, we performed a genome-wide siRNA-based screen; and through this screen, we uncovered cellular functions required for HR and identified proteins that localize to sites of DNA damage. Among positive regulators of HR, we identified networks of pre-mRNA-processing factors and canonical DNA damage response effectors. Within the former, we found RBMX, a heterogeneous nuclear ribonucleoprotein (hnRNP) that associates with the spliceosome, binds RNA, and influences alternative splicing. We found that RBMX is required for cellular resistance to genotoxic stress, accumulates at sites of DNA damage in a poly(ADP-ribose) polymerase 1-dependent manner and through multiple domains, and promotes HR by facilitating proper BRCA2 expression. Screen data also revealed that the mammalian recombinase RAD51 is commonly off-targeted by siRNAs, presenting a cautionary note to those studying HR with RNAi and highlighting the vulnerability of RNAi screens to off-target effects in general. Candidate validation through secondary screening with independent reagents successfully circumvented the effects of off-targeting and set a new standard for reagent redundancy in RNAi screens.

Genetics

homologous recombination

Off-target

RAD51

RBMX

RNAi

screen

Role of the Breast Cancer Susceptibility 2 BRC Repeats in Homologous Recombination

Cealic, Iulia

08 January 2013

Homologous recombination (HR) is a faithful mechanism for the repair of double-stranded DNA breaks (DSBs) and plays a critical role in maintaining the integrity of genomic DNA. The product of the Breast Cancer Susceptibility 2 (BRCA2) gene functions as a recombination mediator in HR-directed repair of DSBs. BRCA2 interacts directly with RAD51, the central recombinase of HR, through highly conserved repetitive motifs of 30-40 amino acids, named BRC repeats, and regulates the formation of the RAD51-ssDNA nucleoprotein filament. There is significant variability in the number of BRC repeats among taxa. However, all mammalian BRCA2 orthologs have eight BRC repeats, which display different characteristics in in vitro studies of RAD51-ssDNA nucleoprotein filament. To test the importance of the number of BRC repeats and to evaluate the role of individual BRC repeats in HR, BRCA2 variants bearing different combinations of BRC repeats were generated using BAC-recombineering, expressed in murine hybridoma cells, and assayed for the ability to stimulate HR using a gene targeting assay. The BRCA2 variant bearing BRC repeats 1 to 4 decreased the efficiency of HR and increased the level of Rad51 protein, whereas the BRCA2 variant bearing BRC repeats 5 to 8 significantly stimulated HR, but had no effect on the level of Rad51. These results supported the hypothesis that BRC repeats are not functionally equivalent, but rather have different, perhaps reinforcing functions in HR. / Canadian Institutes of Health Research

BRCA2

BRC repeats

Homologous recombination

Gene targeting

Rad51

Characterization of Valproic Acid-Initiated Homologous Recombination

Sha, Kevin

12 August 2009

Oxidative stress and histone deacetylase (HDAC) inhibition has been implicated as potential mechanisms in valproic acid (VPA) teratogenicity. Reactive oxygen species (ROS) can target DNA to cause oxidative DNA damage and DNA double strand breaks (DSBs) which can be repaired through homologous recombination (HR). HR is not an error free process and can result in detrimental genetic changes. In this present study we evaluated the role of HDAC inhibition in VPA-initiated HR. HDAC inhibition may indirectly alter repair activity as a result of increased expression of genes involved in HR or indirectly by causing DNA damage which initiates repair. The first objective was to investigate the ability of VPA to cause HDAC inhibition in the Chinese hamster ovary (CHO) 33 cell line. Using immunblotting, an increase in acetylated histone H3 and H4 protein levels was observed throughout 24 hr exposure to 5 mM VPA. Secondly, to investigate whether VPA affects the activity of DNA DSB repair, CHO 33 cells were transfected with either the endonuclease I-SceI plasmid to induce a site specific DSB or the empty plasmid, pGem. However, no increase in the difference in HR between VPA and media exposed I-Sce1 transfected cells compared to cells transfected with pGem was observed, which suggests that VPA does not affect DNA repair activity. Thirdly, to determine if VPA-induced HDAC inhibition increases susceptibility to DNA damage, immunocytochemistry revealed an increase in the number of γ-H2AX foci throughout 24 hr exposure to 5 mM VPA. To determine if oxidative stress may play a role in mediating VPA-induced DNA DSBs, another recombination study was carried out in which cells were pretreated with 400 U/ml of PEG-catalase prior to VPA treatment. The observed protective effect of PEG-catalase against VPA-induced HR and the generation of intracellular ROS by VPA suggest ROS may also play a role in VPA-initiated HR. However, in our DNA oxidation study, no increase in the oxidized nucleosides, 8-hydroxy-2'-deoxyguanosine and 5-hydroxycytosine was observed after VPA treatment. These studies suggest that HDAC inhibition and ROS signalling may play other roles in DNA maintenance and cell cycle arrest in initiating DNA DSBs and HR repair. / Thesis (Master, Pharmacology & Toxicology) -- Queen's University, 2009-08-12 14:27:16.327

Valproic acid

homologous recombination

DNA damage

DNA repair

Molecular determinants of sensitivity to poly(ADP-ribose) polymerase inhibitors in epithelial ovarian cancer

O'Connor, Kevin William

18 June 2016

Less than half of patients with epithelial ovarian cancer (EOC) survive five years following diagnosis, underscoring the imperative need for improved treatment. Many patients, including those with advanced disease, initially respond to platinum agents, which constitute the backbone of therapy. However, tumors ultimately become resistant, rendering further treatment ineffective. Additionally, the poor tolerability of these agents warrants the exploration of more targeted treatments – one such strategy is exploiting synthetic lethal genetic relationships. Recent genomic sequencing efforts have revealed that as many of half of EOCs have homologous recombination (HR) alterations. HR is a critical pathway for the repair of platinum-induced ICLs, thus compromised HR is hypothesized to explain the initial response to chemotherapy in many patients. Accordingly, women whose tumors harbor mutations in the critical HR genes, BRCA1 or BRCA2 (BRCA1/2), demonstrate improved prognosis. BRCA1/2 mutations also confer exquisite sensitivity to inhibitors of the enzyme, poly(ADP-ribose) polymerase 1 (PARPis), hence loss of BRCA1/2 and PARP1 is synthetic lethal. A number of models have been proposed to explain this synthetic lethality, yet a consensus model that accounts for the diverse cellular roles of BRCA1/2 and PARP1 has yet to be established. Delineating the precise molecular underpinnings of PARPi action in BRCA1/2-deficient cells will aid clinicians in identifying the appropriate population of women with EOC likely to benefit from PARPi treatment and provide insight into resistance mechanisms that arise in these patients. Combining this approach with retrospective analysis of PARPi clinical trials will best define the proper indication for PARPi in EOC and other human cancers.

Oncology

PARP inhibitors

Homologous recombination

Ovarian cancer

Synthetic lethality

Caractérisation des interactions physiques et fonctionnelles entre le facteur d’assemblage de la chromatine, CAF-1, et des facteurs de la recombinaison homologue au cours de la réparation de l’ADN / Characterization of Physical and Functional Interactions Between the Chromatin Assembly Factor 1, CAF-1, and Homologous Recombination Factors During DNA Repair

Dai, Dingli

21 December 2018

L’ADN est constamment exposé à des insultes génotoxiques endogènes et exogènes. Plusieurs mécanismes de réparations de l’ADN sont mis en œuvre pour préserver la stabilité du génome et de l’épigénome. La recombinaison homologue (RH) joue un rôle central dans la réparation des cassures double brin de l’ADN (DSBs) et le redémarrage des fourches de réplication en réponse à un stress réplicatif. Ces deux processus sont tous deux couplés à l’assemblage de la chromatine. Le facteur d’assemblage de la chromatine 1 (CAF-1) est un chaperon d’histone conservé au cours de l’évolution qui fonctionne dans le processus d’assemblage des nucléosomes couplé à la réparation de l’ADN et à la réplication, en déposant sur l’ADN les tétramères d’histones (H3-H4)2 nouvellement synthétisés. Chez la levure Schizosaccharomyces pombe, le complexe CAF-1 est constitué de trois sous-unités, Pcf1, Pcf2 et Pcf3. Il a été montré que CAF-1 agit dans l’étape de synthèse de l’ADN durant le processus de réplication dépendante de la recombinaison (RDR) et protège le désassemblage des D-loop par l’hélicase Rqh1, membre de la famille des hélicases RecQ. Dans cette étude, nous avons adressé le rôle de CAF-1 pendant la réparation de l’ADN par recombinaison homologue chez la levure Schizosaccharomyces pombe. Par l’utilisation d’approches in vivo et in vitro, nous avons validé des interactions protéines-protéines au sein d’un complexe contenant Rqh1, CAF-1, PCNA, et l’Histone H3. Nous avons montré que Rqh1 interagit avec Pcf1 et avec Pcf2 indépendamment l’un de l’autre, et que l’interaction Rqh1-Pcf1 est stimulée par des dommages à l’ADN. Nous avons mis en place une méthode d’analyse de liaison à la chromatine pour suivre l’association de CAF-1 à la chromatine en réponse aux dommages à l’ADN. Nous avons observé qu’un stress réplicatif, mais pas l’induction de cassures double brin de l’ADN, favorise l’association de CAF-1 à la chromatine. Nous avons identifié plusieurs facteurs de la RH nécessaire pour l’association de CAF-1 à la chromatine en réponse à un stress réplicatif. De plus, nous avons mis en évidence des interactions physiques entre Pcf1 et des facteurs de la recombinaison homologue, parmi lesquels RPA et Rad51. Nos données suggèrent que CAF-1 pourrait s’associer aux sites de synthèse d’ADN dépendent de la recombinaison via son interaction avec des facteurs de la RH. L’ensemble des données de cette étude contribuent à renforcer le role de CAF-1 couplé à réparation de l’ADN, et révèlent une interconnexion entre les facteurs de la RH et l’assemblage de la chromatine. / DNA is constantly exposed to both endogenous and exogenous genotoxic insults. Multiple DNA repair mechanisms are exploited to guard the genome and epigenome stability. Homologous recombination (HR) plays a major role in repairing DNA double strand breaks (DSBs) and restarting stalled replication forks under replicative stress. These two processes are both coupled to chromatin assembly. Chromatin assembly factor 1 (CAF-1) is a highly conserved histone chaperone known to function in a network of nucleosome assembly coupled to DNA repair and replication, by depositing newly synthesized histone (H3-H4)2 tetramers onto the DNA. The fission yeast CAF-1 complex consists of three subunits Pcf1, Pcf2 and Pcf3. CAF-1 has been previously reported to act at the DNA synthesis step during the process of recombination-dependent replication (RDR) and protects the D-loop from disassembly by the RecQ helicase family member, Rqh1. In this study, we addressed the role of CAF-1 during homologous-recombination-mediated DNA repair in fission yeast.Using in vivo and in vitro approaches, we validated interactions within a complex containing Rqh1, CAF-1, PCNA, and Histone H3. We showed that Rqh1 interacts with both Pcf1 and Pcf2 independently of each other, and the Pcf1-Rqh1 interaction is stimulated by DNA damage. We developed an in vivo chromatin binding assay to monitor the association of CAF-1 to the chromatin upon DNA damage. We observed that replication stress but not double strand break favors CAF-1 association to the chromatin. We identified that several HR factors are required for CAF-1 association to the chromatin upon replication stress. In support of this, we have identified physical interactions between Pcf1 and HR factors, including RPA and Rad51. Our data suggest that CAF-1 would associate with the site of recombination-dependent DNA synthesis through physical interactions with HR factors. Put together, this work contributes to strengthening the role of CAF-1 coupled to DNA repair, and reveals the crosstalk between HR factors and chromatin assembly.

Recombinaison homologue

Réparation de l'ADN

Chromatine

Homologous recombination

DNA repair

Chromatin

The E3 ligase RFWD3 promotes timely removal of both RPA and RAD51 from DNA damage sites to facilitate homologous recombination / E3ユビキチン化酵素RFWD3はRPAとRAD51を適時除去することで相同組換えを促進する

Inano, Shojiro

25 September 2017

京都大学 / 0048 / 新制・課程博士 / 博士(医学) / 甲第20668号 / 医博第4278号 / 新制||医||1024(附属図書館) / 京都大学大学院医学研究科医学専攻 / (主査)教授 武田 俊一, 教授 岩井 一宏, 教授 清水 章 / 学位規則第4条第1項該当 / Doctor of Medical Science / Kyoto University / DFAM

Fanconi anemia

Homologous recombination

ICL repair

RFWD3

RAD51

RPA

490