The Role of 53BP1 and its Phosphorylation in the DNA Damage Response

Harding, Shane Michael

12 December 2012

The tumour suppressor p53-binding protein 1 (53BP1) is phosphorylated following DNA double strand breaks (DSBs); however, little is understood about the upstream signaling pathways that control this phosphorylation. Additionally, it is not known how these processes combine with 53BP1 to control the survival of cells following DNA damage such as that imparted by ionizing radiation (IR), which is the basis of radiotherapy. In this thesis, I have shown that 53BP1 is phosphorylated specifically in S-phase cells, but not relocalized to intranuclear foci, in response to severe oxygen stress. This occurs with only partial dependence on the ATM kinase (Chapter 2). Following IR, I find that both ATM and DNA-PKcs contribute to intranuclear phosphorylated 53BP1 foci, but that this phosphorylation is independent of proximal signaling molecules that control the localization of 53BP1 to initial DSBs (Chapter 3). Furthermore, I show that 53BP1 loss confers sensitivity to IR and this can be further augmented by inhibition of ATM and DNA-PKcs kinases suggesting that there are both 53BP1-dependent and -independent pathways of survival from IR (Chapter 4). These findings may have important implications for molecular pathology and personalized medicine as 53BP1 has recently been found to be activated or lost in subsets of human tumours. I have collaborated to initiate the development of a novel system to interrogate the implications of 53BP1 loss as traditional siRNA approaches in human cancer cells were not feasible (Chapter 5 and Appendix 2). This system can be used in vivo as tumour xenografts to further understand how 53BP1 and the tumour microenvironment interact endogenously and in response to IR. I also present the possibility and proof of concept for the use of 53BP1 as a biomarker in primary human prostate cancer tissue where little is known about 53BP1 biology (Chapter 5).

DNA Damage

Genetic Instability

Cancer

Ionizing radiation

53BP1

Hypoxia

Cell cycle

Radiosensitivity

0379

0307

0760

Stabilité du génome et rôle des INGs dans la réponse aux dommages de l'ADN / Genome stability and involvement of INGs proteins in DNA double strand break repair

Mouche, Audrey

30 June 2017

ING2 et ING3 (Inhibitor of Growth 2 and 3) sont des protéines suppressives de tumeurs appartenant à une famille de 5 protéines ING1 à ING5. Le travail de thèse a consisté à étudier l’implication des protéines ING2 et ING3 dans la réponse aux dommages à l’ADN. Les fonctions d’ING3 en tant que gène suppresseur de tumeur sont peu connues. L’étude principale a été d’analyser l’impact de l’inhibition d’ING3 sur la réponse aux cassures double brins de l’ADN. De plus, une étude antérieure de l’équipe a observé que l’inhibition de la protéine ING2 était associée à l’accumulation de H2AX, un marqueur des cassures double brins de l’ADN. Ainsi nous avons également cherché à savoir si ING2 pouvait jouer un rôle dans la signalisation et la réparation des cassures double brins de l’ADN. Nous montrons pour la première fois un rôle d’ING3 dans la signalisation et la réparation des cassures double brins. En effet, ING3 joue un rôle crucial dans la signalisation des cassures permettant la phosphorylation et l’activation de la kinase ATM. En accord avec ces fonctions, ING3 est impliquée dans la réparation des cassures double brins par NHEJ et HR ainsi que dans la recombinaison de classe des immunoglobulines. Nous avons également montré l’implication d’ING2 dans la réponse aux cassures double brins de l’ADN. En effet, ING2 est nécessaire pour le recrutement de la protéine médiatrice de la réponse aux dommages 53BP1. Nos travaux montrent que ING2 est nécessaire pour la réparation par le mécanisme de la NHEJ. L’étude de son implication dans le mécanisme de recombinaison de classe des immunoglobulines montre qu’ING2 est un acteur essentiel de la voie classique de la NHEJ. Ces travaux identifient, pour la première fois, une fonction de type « caretaker » pour ING3 dans la réponse aux cassures doubles brins. Nous montrons une nouvelle fonction de type « caretaker » pour ING2 qui joue un rôle dans la stabilité du génome via son implication dans la réponse aux cassures double brins de l’ADN. / ING2 and ING3 (Inhibitor of Growth 2 and 3) are tumor suppressor proteins belonging to the ING family (ING1 to ING5). The aim of my research project was to analyze the involvement of ING2 and ING3 proteins in response to DNA damages. The functions of ING3 as a tumor suppressor gene are little known. In the present study, we have investigated the impact of ING3 inhibition in response to DNA double strand breaks. Previous study in the lab showed . In addition, a previous study in the lab found that inhibition of ING2 protein is associated with the accumulation of H2AX, a marker of DNA double-strand breaks. Thus, we also demonstrate that ING2 plays a role in the signaling and repair of DNA double-strand breaks. In the present study, we describe for the first time the involvement of ING3 in the signaling and repair of DNA double-strand breaks. ING3 allowed the phosphorylation and activation of the ATM kinase and the repair of double strand breaks by NHEJ and HR as well as in immunoglobulin class switch recombination. We also show the involvement of ING2 in this process. Indeed, ING2 is necessary for 53BP1 recruitment in response to DNA damages and repair by the mechanism of NHEJ. ING2 was also an essential actor for the class switch recombination demonstrated that ING2 is an essential actor of the classical NHEJ pathway. This work identifies, for the first time, a "caretaker" function for ING3 in the response to DNA double strand breaks; and . We show a new caretaker function for ING2 that plays a role in the stability of the genome through its involvement in DNA damage response.

Ing2

Ing3

Gène suppresseur de tumeur

Cancer

Cassures double brin de l'ADN

Instabilité génomique

53bp1

Elucidating Mechanisms of IgH Class Switch Recombination Involving Switch Regions and Double Strand Break Joining

Zhang, Tingting

January 2011

During IgH class switch recombination (CSR) in mature B lymphocytes, activation-induced cytidine deaminase (AID) initiates DNA double strand breaks (DSBs) within switch (S) regions flanking different sets of the IgH locus (IgH) constant \((C_H)\) region exons. End-Joining of DSBs in the upstream donor S region (Sm) to DSBs in a downstream acceptor S region \((S_{acc})\) replaces the initial set of \(C_H\) exons, Cm, with a set of downstream \(C_H\) exons, leading to Ig class switching from IgM to another IgH class (e.g., IgG, IgE, or IgA). In addition to joining to DSBs within another S region, AID-induced DSBs within a given S region are often rejoined or joined to other DSBs in the same S region to form internal switch deletions (ISDs). ISDs were frequently observed in Sm but rarely in \(S_{acc}s\), suggesting that AID targeting to \(S_{acc}s\) requires prior recruitment to Sm. To test this hypothesis, we assessed CSR and ISDs in B cells lacking Sm and found that AID frequently targets downstream \(S_{acc}s\) independently of Sm. These studies also led us to propose an alternative pathway of "downstream" IgE class switching that involves joining of DSBs within the downstream \(S\gamma1\) and \(S\epsilon\) regions as a first step before joining of \(S\mu\) to the hybrid downstream S region. To further elucidate the CSR mechanism, we addressed the long-standing question of whether S region DSBs during CSR involves a direction-specific mechanism similar to joining of RAG1/2 endonuclease-generated DSBs during V(D)J recombination. We used an unbiased high throughput method to isolate junctions between I-SceI meganuclease-generated DSBs at a target site that replaces the IgH \(S\gamma1\) region and other genomic DSBs of endogenous origin. Remarkably, we found that the I-SceI-generated DSBs were joined to both upstream DSBs in \(S\mu\) and downstream DSBs in \(S\epsilon\) predominantly in orientations associated with joining during productive CSR. This process required the DSB response factor 53BP1 to maintain the orientation-dependence, but not the overall levels, of joining between these widely separated IgH breaks. We propose that CSR exploits a mechanism involving 53BP1 to enhance directional joining of DSBs within IgH in an orientation that leads to productive CSR.

53BP1

class switch recombination

double strand break repair

IgH

switch regions

immunology

Molekulární mechanismy signalizace a terminace checkpointu / Molecular mechanisms of checkpoint signalling and termination

Benada, Jan

January 2017

Cells employ an extensive signalling network to protect their genome integrity, termed DNA damage response (DDR). The DDR can trigger cell cycle checkpoints which prevent cell cycle progression and allow repair of DNA damage. The failures in these safeguarding mechanism are represented by serious human malignancies, most predominantly by cancer development. This work aims to contribute to the understanding of how do the cells negatively regulate DDR and cell cycle checkpoint signalling. We focused mainly on Wip1 (PPM1D) phosphatase, which is a major negative regulator of DDR and is indispensable for checkpoint recovery. Firstly, we have shown that Wip1 is degraded during mitosis in APC-Cdc20 dependent manner. Moreover, Wip1 is phosphorylated at multiple residues during mitosis, resulting in inhibition of its enzymatic activity. We suggest that the abrogation of Wip1 activity enables cells to react adequately even to low levels of DNA damage encountered during unperturbed mitosis. In the following publication, we have investigated why the mitotic cells trigger only early events of DDR and do not proceed to the recruitment of DNA repair factors such as 53BP1. We showed that 53BP1 is phosphorylated within its ubiquitination-dependent recruitment domain by CDK1 and Plk1. These phosphorylations prevents...

Regulace buněčné odpovědi na poškozenou DNA pomocí skládání komplexu MRN šaperonovým komplexem R2TP a pomocí kontroly buněčné lokalizace proteinu 53BP1. / Regulation of the DNA damage response by R2TP mediated MRN complex assembly and control of 53BP1 localisation.

Von Morgen, Patrick

January 2017

DNA double strand breaks are the most dangerous type of DNA damage. The MRN complex and 53BP1 have essential functions in the repair of DNA double strand breaks and are therefore important for maintaining genomic stability and preventing cancer. DNA double strand breaks are repaired by two main mechanisms - homologous recombination and non- homologous end joining. The MRN complex senses DNA double strand breaks and activates a cascade of posttranslational modifications that activates and recruits other effector proteins. In addition MRN mediated resection is important for removing adducts in non-homologous end joining and creating single stranded DNA required for homologous recombination. 53BP1 is recruited to DNA double strand breaks by site specific ubiquitinations and inhibits DNA resection, thereby promoting non-homologous end joining at the expense of homologous recombination. In this thesis we show that MRE11 binds to the R2TP chaperone complex through a CK2 mediated phosphorylation. Knockdown of R2TP or mutating the MRE11 binding site leads to decreased MRE11 levels and impaired DNA repair. Similar phenotype has been observed in cells from patients with ataxia-telangiectasia-like disorder (ATLD), containing MRE11 deletion mutation which is missing the R2TP complex binding site. Based on R2TP...

Functions of BRCA1, 53BP1 and SUMO isoforms in DNA double-strand break repair in mammalian cells

Hu, Yiheng

18 September 2014

No description available.

Molecular Biology

Double-strand break repair

BRCA1

53BP1

SUMO

RNF8

RNF168

ionizing radiation

3-D Genome organization of DNA damage repair / Rôle de l’organisation 3D du génome dans la réparation des dommages à l'ADN

Banerjee, Ujjwal Kumar

18 December 2017

Notre génome est constamment attaqué par des facteurs endogènes et exogènes qui menacent son intégrité et conduisent à différents types de dommages. Les cassures double brins (CDBs) font partie des dommages les plus nuisibles car elles peuvent entraîner la perte d'information génétique, des translocations chromosomiques et la mort cellulaire. Tous les processus de réparation se déroulent dans le cadre d'une chromatine hautement organisée et compartimentée. Cette chromatine peut être divisée en un compartiment ouvert transcriptionnellement actif (euchromatine) et un compartiment compacté transcriptionnellement inactif (hétérochromatine). Ces différents degrés de compaction jouent un rôle dans la régulation de la réponse aux dommages à l’ADN. L'objectif de mon premier projet était de comprendre l'influence de l'organisation 3D du génome sur la réparation de l'ADN. Pour cela, j’ai utilisé deux approches complémentaires dans le but d’induire et de cartographier les CDBs dans le génome de souris. Mes résultats ont mis en évidence un enrichissement de γH2AX, facteur de réparation des dommages à l’ADN, sur différentes régions du génome de cellules souches embryonnaires de souris, et ont également montré que les dommages persistent dans l’hétérochromatine, contrairement à l’euchromatine qui est protégée des dommages. Pour mon deuxième projet, j'ai cartographié l'empreinte génomique de 53BP1, facteur impliqué dans la réparation des CDBs, dans des cellules U2OS asynchrones et des cellules bloquées en G1 afin d’identifier de nouveaux sites de liaison de 53BP1. Mes résultats ont permis d’identifier de nouveaux domaines de liaison de 53BP1 couvrant de larges régions du génome, et ont montré que ces domaines de liaison apparaissent dans des régions de réplication moyenne et tardive. / Our genome is constantly under attack by endogenous and exogenous factors which challenge its integrity and lead to different types of damages. Double strand breaks (DSBs) constitute the most deleterious type of damage since they maylead to loss of genetic information, translocations and cell death. All the repair processes happen in the context of a highly organized and compartmentalized chromatin. Chromatin can be divided into an open transcriptionally active compartment (euchromatin) and a compacted transcriptionally inactive compartment (heterochromatin). These different degrees of compaction play important roles in regulating the DNA damage response. The goal of my first project was to understand the influence of 3D genome organization on DNA repair. I used two complementary approaches to induce and map DSBs in the mouse genome. My results have shown that enrichment of the DNA damage repair factor γH2AX occurs at distinct loci in the mouse embryonic stem cell genome and that the damage persists in the heterochromatin compartment while the euchromatin compartment is protected from DNA damage. For my second project, I mapped the genomic footprint of 53BP1, a factor involved in DSBs repair, in asynchronous and G1 arrested U2OS cells to identify novel 53BP1 binding sites. My results have identified novel 53BP1 binding domains which cover broad regions of the genome and occur in mid to late replicating regions of the genome.

Réponse aux dommages à l’ADN

Cassures Double Brin

ChIP-Seq

Cellules souches embryonnaire

Organisation de la chromatine

ΓH2AX

53bp1

DNA damage response

Double strand breaks

ChIP-Seq

Embryonic stem cells

Chromatin organization

ΓH2AX

53bp1

572.8

Hereditary predisposition to breast cancer—evaluation of candidate genes

Rapakko, K. (Katrin)

04 May 2007

Abstract In Western countries, breast and ovarian cancer are among the most frequent malignancies affecting women. Approximately 5–10% of the cases in the general population have been suggested to be attributed to inherited disease susceptibility. BRCA1 and BRCA2 are the main genes associated with predisposition to breast and ovarian cancer. Mutations in these two genes explain a major part of the families displaying a large number of early-onset breast and/or ovarian cancers, but at least one third of the cases appear to be influenced by other, as yet unidentified genes. Therefore, it is likely that defects in other cancer predisposing genes, perhaps associated with lower disease penetrance and action in a polygenic context, will also be discovered. In the present study, the contribution of germline mutations in putative breast and/or ovarian cancer susceptibility genes, based on their biological function, has been investigated in Finnish breast cancer families. The role of large genomic deletions or other rearrangements in the BRCA1 and BRCA2 genes was evaluated by Southern blot analysis, and mutation analysis of TP53, RAD51, the BRC repeats of BRCA2, and 53BP1 was performed by conformation sensitive gel electrophoresis and DNA sequencing. Germline TP53 mutations were searched for in 108 Finnish breast cancer families without BRCA1 or BRCA2 alterations. In this study, the pathogenic TP53 germline mutation, Arg248Gln, was identified in only one family. This family showed a strong family history of breast cancer and other cancers also fulfilling the criteria for Li-Fraumeni-like syndrome. Germline TP53 mutations are expected to be found in cancer families with clinical features seen in Li-Fraumeni or Li-Fraumeni-like syndromes. In this study, large deletions in BRCA1 and BRCA2 were not observed in 82 breast and/or ovarian cancer families. Likewise, no disease-related aberrations were detected in RAD51, the BRC repeats of BRCA2 or 53BP1 in the 126 breast and/or ovarian cancer families studied. The obtained results were validated by comparing to the occurrence in 288–300 female cancer-free control individuals. These results do not support the hypothesis that alterations in these particular genomic regions play a significant role in breast cancer predisposition in Finland. Thus, there are still genes to be discovered to explain the molecular background of breast cancer.

53BP1

BRC repeats

BRCA1

BRCA2

DNA mutational analysis

RAD51

TP53

breast neoplasms

germ-line mutation

large deletion

Post-replicative resolution of under-replication

Carrington, James T.

January 2017

The evolutionary pressure to prevent re-replication by inactivating licensing during S phase leaves higher-eukaryotes with large genomes, such as human cells, vulnerable to replication stresses. Origins licensed in G1 must be sufficient to complete replication as new origins cannot be licensed in response to irreversible replication fork stalling. Interdisciplinary approaches between cellular biology and biophysics predict that replication of the genome is routinely incomplete in G2, even in the absence of external stressors. The frequency of converging replication forks that never terminate due to irreversible stalling (double fork stall), which result in a segment of unreplicated DNA, was modelled using high quality origin-mapping data in HeLa and IMR-90 cells. From this, hypotheses were generated that related an increase in unreplicated segments of DNA to reduced functional origin number. Presented in this thesis is the confirmation of this relation by quantifying chromosome mis-segregation and DNA damage responses when origin number was reduced using RNAi against licensing factors. The number of ultrafine anaphase bridges and 53BP1 nuclear bodies are in remarkable concordance with the theoretical predictions for the number of double fork stalls, indicating that cells are able to tolerate under-replication through such post-replicative cellular responses. 53BP1 preferentially binds to chromatin associated with large replicons, and functions synergistically with dormant origins to protect the stability of the genome. Additional candidates, inspired by common fragile site research, have also been characterised as responders to spontaneous under-replication, and include FANCD2 and MiDAS, which function in early mitosis to facilitate completion of replication before cells enter anaphase. In conclusion, a series of mechanisms that sequentially function throughout the cell cycle protects the stability of the human genome against inevitable spontaneous under-replication brought about by its large size.

DNA Damage Response of Normal Epidermis in the Clinical Setting of Fractionated Radiotherapy : Evidence of a preserved low-dose hypersensitivity response

Qvarnström, Fredrik

January 2009

Investigations of DNA damage response (DDR) mechanisms in normal tissues have implications for both cancer prevention and treatments. The accumulating knowledge about protein function and molecular markers makes it possible to directly trace and interpret cellular DDR in a tissue context. Using immunohistochemical techniques and digital image analysis, we have examined several principal DDR events in epidermis from patients undergoing fractionated radiotherapy. Acquiring biopsies from different regions of the skin provides the possibility to determine in vivo dose response at clinically relevant dose levels throughout the treatment. A crucial event in cellular DDR is the repair of DNA double strand breaks (DSBs). These serious lesions can be directly visualised in cells by detecting foci forming markers such as γH2AX and 53BP1. Our results reveal that DSB-signalling foci can be detected and quantified in paraffin-embedded tissues. More importantly, epidermal DSB foci dose response reveals hypersensitivity, detected as elevated foci levels per dose unit, for doses below ~0.3Gy. The low-dose hypersensitive dose response is observed throughout the treatment course and also in between fractions: at 30 minutes, 3 hours and 24 hours following delivered fractions. The dose response at 24 hours further reveals that foci levels do not return to background levels between fractions. Furthermore, a low-dose hypersensitive dose response is also observed for these persistent foci. Investigations of end points further downstream in the DDR pathways confirmed that the low-dose hypersensitivity was preserved for: the checkpoint regulating p21 kinase inhibitor; mitosis suppression; apoptosis induction and basal keratinocyte reduction. Our results reveal preserved low-dose hypersensitivity both early and late in the DDR pathways. A possible link between the dose-response relationships is therefore suggested. The preserved low-dose hypersensitivity is a cause for re-evaluation of the risks associated with low-dose exposure and has implications for cancer treatments, diagnostics and radiation protection.

DNA damage response

low-dose hypersensitivity

dose response

normal tissue

epidermis

keratinocyte

fractionated radiotherapy

DNA double strand break

DSB

foci

γH2AX

53BP1

checkpoint

p21

apoptosis

mitosis

Oncology

Onkologi