Lentivirus-meditated frataxin gene delivery reverses genome instability in Friedreich ataxia patient and mouse model fibroblasts

Khonsari, Hassan

January 2015

Friedreich ataxia (FRDA) is a progressive neurodegenerative disease with primary sites of pathology in the large sensory neurons of the dorsal root ganglia (DRG) and dentate nucleus of the cerebellum. FRDA is also often accompanied by severe cardiomyopathy and diabetes mellitus. FRDA is caused by loss of frataxin (FXN) expression, which is due to GAA repeat expansion in intron 1 of the FXN gene. Frataxin is a mitochondrial protein important in iron-sulphur cluster (ISC) biogenesis and in the electron transport chain (ETC). As a consequence of impaired mitochondrial energy metabolism, FRDA cells show increased levels of and sensitivity to oxidative stress, which is known to be associated with genome instability. In this study, we investigated DNA damage/repair in relation to FXN expression via immunostaining of γ-H2AX, a nuclear protein that is recruited to DNA double strand breaks (DSBs). We found FRDA patient and YG8sR FRDA mouse model fibroblasts to have inherently elevated DNA DSBs (1.8 and 0.9 foci/nucleus) compared to normal fibroblasts (0.6 and 0.2 foci/nucleus, in each case P < 0.001). By delivering the FXN gene to these cells with a lentivirus vector (LV) at a copy number of ~1/cell, FXN mRNA levels reached 48 fold (patient cells) and 42 fold (YG8sR cells) and protein levels reached 20 fold (patient cells) and 3.5 fold (YG8sR cells) that of untreated fibroblasts, without observable cytotoxicity. This resulted in a reduction in DNA DSB foci to 0.7 and 0.43 (in each case P < 0.001) in human and YG8sR fibroblasts, respectively and an increase in cell survival to that found for normal fibroblasts. We next irradiated the FRDA fibroblasts (2Gy) and measured their DSB repair profiles. Both human and mouse FRDA fibroblasts were unable to repair damaged DNA. However, repair returned to near normal levels following LV FXN gene transfer. Our data suggest frataxin may be important for genome stability and cell survival by ensuring ISC for DNA damage repair enzymes or may be required directly for DNA DSB repair.

616.8

Elucidating the role of altered DNA damage response in Nup98-associated leukaemia

Nilles, Nadine

01 March 2018

Acute myeloid leukaemia is a heterogeneous disease characterized by uncontrolled proliferation of neoplastic haematopoietic precursor cells, which leads to the disruption of normal haematopoiesis and bone marrow failure. Impaired haematopoiesis is often associated with balanced chromosomal translocations that involve the nucleoporin Nup98 fused to around 30 different partner genes, such as the homeobox genes HOXA9 and PMX1. Nup98-associated AML is characterized by poor prognosis and poor treatment outcome for the patients. The aim of the study was to elucidate the mechanisms underlying chemotherapy-resistance. Previous experiments showed that the expression of Nup98 fusion proteins leads to changes in nuclear organization. Based on these observations, we hypothesize that the expression of Nup98 fusion proteins affect DNA double-strand break (DSB) repair. Our work shows that the expression of Nup98-HoxA9 and Nup98-HHEX in U2OS cells does not induce any DSBs. Further, we examined the repair phenotype of exogenously induced DSBs. Experiments carried out using etoposide (ETO) or neocarzinostatin (NCS) revealed that Nup98 fusion proteins affect non-homologous end joining (NHEJ). The second major DSB repair pathway, homologous recombination (HR), remains unaffected by Nup98 fusion proteins. The repair phenotype showed that at most timepoints analyzed, cells expressing Nup98 fusion proteins present less DSBs that control cells. We further performed single cell gel electrophoresis assays, also called COMET assay. This assay determines the amount of broken DNA at the single cell level. COMET assays showed that cells expressing Nup98-HoxA9 get equally damaged as control cells. Taken together, these results show that Nup98-HoxA9 induces faster DNA repair by affecting NHEJ. Additional experiments, pointed toward a role of p53 in the effect of Nup98 fusion proteins on DSB repair. Monitoring the repair phenotype in a wild-type and p53 depletion background, revealed that the effect of Nup98-HoxA9 on NHEJ is partially p53 dependent. A further search for the potentially implicated factor in the accelerated NHEJ remained inconclusive so far. In conclusion, Nup98-HoxA9 induces accelerated NHEJ in a partially p53-dependent manner. / Option Biologie moléculaire du Doctorat en Sciences / info:eu-repo/semantics/nonPublished

Sciences humaines

Biologie moléculaire

<em>ATM</em>, <em>ATR</em> and Mre11 complex genes in hereditary susceptibility to breast cancer

Pylkäs, K. (Katri)

10 April 2007

Abstract Mutations in BRCA1 and BRCA2 explain only about 20% of familial aggregation of breast cancer, suggesting involvement of additional susceptibility genes. In this study five DNA damage response genes, ATM, ATR, MRE11, NBS1 and RAD50, were considered as putative candidates to explain some of the remaining familial breast cancer risk, and were screened for germline mutations in families displaying genetic predisposition. Analysis of ATM indicated that clearly pathogenic mutations seem to be restricted to those reported in ataxia-telangiectasia (A-T). However, a cancer risk modifying effect was suggested for a combination of two ATM polymorphisms, 5557G>A and IVS38-8T>C, as this allele seemed to associate with bilateral breast cancer (OR 10.2, 95% CI 3.1–33.8, p = 0.001). The relevance of ATM mutations, originally identified in Finnish A-T patients, in breast cancer susceptibility was evaluated by a large case-control study. Two such alleles, 6903insA and 7570G>C, in addition to 8734A>G previously associated with breast cancer susceptibility, were observed. The overall mutation frequency in unselected cases (7/1124) was higher than in controls (1/1107), but a significantly elevated frequency was observed only in familial cases (6/541, p = 0.006, OR 12.4, 95% CI 1.5–103.3). These three mutations showed founder effects in their geographical occurrence, and had different functional consequences at protein level. In ATR no disease-related mutations were observed, suggesting that it is not a breast cancer susceptibility gene. The mutation screening of the Mre11 complex genes, MRE11, NBS1 and RAD50, revealed two novel potentially breast cancer associated alleles: NBS1 Leu150Phe and RAD50 687delT were observed in 2.0% (3/151) of the studied families. The subsequent study of newly diagnosed, unselected breast cancer cases indicated that RAD50 687delT is a relatively common low-penetrance susceptibility allele in Northern Finland (cases 8/317 vs. controls 6/1000, OR 4.3, 95% CI 1.5–12.5, p = 0.008). NBS1 Leu150Phe (2/317) together with a novel RAD50 IVS3-1G>A mutation (1/317) was also observed, both being absent from controls. Loss of the wild-type allele was not observed in the tumors of the studied mutation carriers, but they all showed an increase in chromosomal instability of peripheral T-lymphocytes. This suggests an effect for RAD50 and NBS1 haploinsufficiency on genomic integrity and susceptibility to cancer.

ATM

ATR

DNA double-strand break response

MRE11

NBS1

RAD50

breast neoplasms

genetic predisposition to disease

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

DNA damage responses in the context of the cell division cycle

Giunta, Simona

January 2010

During my PhD, I have investigated aspects of the DNA damage response (DDR) in the context of three different cellular scenarios: DNA damage signalling in response to double-strand breaks during mitosis, coordination of DNA replication with DNA damage responses by regulation of the GINS complex, and checkpoint activation by the prototypical checkpoint protein Rad9. Here, I show that mitotic cells treated with DNA break-inducing agents activate a 'primary' DDR, including ATM and DNA-PK-dependent H2AX phosphorylation and recruitment of MDC1 and the MRN complex to damage sites. However, downstream DDR events and induction of a DNA damage checkpoint are inhibited in mitosis, with full DDR activation only ensuing when damaged mitotic cells enter G1. In addition, I provide evidence that induction of a primary DDR in mitosis is biologically important for cell viability. The GINS complex is an evolutionarily conserved component of the DNA replication machinery and may represent an ideal candidate for transferring the DNA damage signal to the replication apparatus. Here, I show the identification of a consensus 'SQ' PIKK phosphorylation motif at the carboxyl end of the GINS complex subunit, Psf1. In Saccharomyces cerevisiae, switching the conserved serine to a glutamic acid is lethal, indicating that the site is crucial for the protein's function. Moreover, in human cells, I identified UV-DDB, a heterodimeric complex involved in NER repair, as a binding partner that specifically interacts with the Psf1 C-terminus in vitro. Finally, I discuss my findings in characterizing functional interactions between Rad9 and Chk1 in S. cerevisiae. I show that specific consensus CDK sites within Rad9 N-terminus are essential to enable Chk1 phosphorylation and activation, and that MCPH1, a human homologue of Rad9, may share a conserved function in binding and activating Chk1, underscoring the evolutionarily conservation of checkpoint activation mechanisms.

572.8

Role of Caspase 3/Caspase Activated DNase induced DNA Strand Breaks during Skeletal Muscle Differentiation.

Larsen, Brian D.

January 2012

Cell fate decisions incorporate distinct and overlapping mechanisms. The activity of caspase 3 was initially understood to be a cell death restricted event, however numerous studies have implicated this enzyme in the regulation of both differentiation and proliferation. How the activity of caspase 3 promotes a non-death cell fate remains unclear. Here we examine the role caspase 3 activity plays during skeletal muscle differentiation; in particular we explore the hypothesis that the mechanism of inducing DNA strand breaks during cell death is also a key feature of differentiation, albeit with a distinctly different outcome. We delineate the transient formation of Caspase 3/Caspase activated DNase (CAD) dependent DNA strand breaks during differentiation. The formation of these breaks is essential for differentiation and the regulation of specific genes. In particular expression of the cell cycle inhibitor p21 is related to the formation of a DNA strand break within the gene’s promoter element. Further, we explored the genome wide association of CAD using Chromatin Immunoprecipitation coupled to high through put sequencing (ChIP-seq). This approach identified a potential role for Caspase3/CAD in regulating the expression of Pax7. Here, a CAD directed DNA strand break in the Pax7 gene is correlated with decreased Pax7 expression, an outcome that has been shown to be critical for progress of the myogenic differentiation program. The regulation of Pax7 expression through a CAD induced DNA strand break raises an intriguing connection between this regulation and oncogenic transformation observed in alveolar rhabdomyosarcoma. The putative site of CAD induced DNA strand breaks that promote decreased Pax7 expression during differentiation corresponds to site of chromosomal translocations responsible for Pax7 fusion events in alveolar rhabdomyosarcoma.

Cell Differentiation

Caspase

Caspase-activated DNase

DNA strand breaks

Gene Expression

Cell Death

Intégrité de la chromatine au cours de la réparation des cassures doubles brins méiotiques chez Saccharomyces cerevisiae / Chromatin integrity during meiotic double strand break repair in Saccharomyces cerevisiae

Brachet, Elsa

23 September 2014

Au cours de la méiose, des centaines de cassures doubles brins (CDB) sont générées et réparées par recombinaison homologue. Ces CDB peuvent être réparés par deux voies différentes donnant lieu à des crossing-overs (CO) ou des non crossing-overs (NCO). Le choix entre les deux voies est finement régulé pour assurer un nombre suffisant de CO; les facteurs influençant ce choix n’ont pas encore été bien caractérisés. L’environnement chromatinien pourrait jouer un rôle important dans ce processus.Peu d’études ont été réalisées sur l’influence de la chromatine sur la recombinaison méiotique. Le but de ma thèse a été de caractériser les facteurs chromatiniens nécessaires au remaniement de la chromatine pendant la recombinaison méiotique chez Saccharomyces cerevisiae.J’ai pu montrer que CAF-1 (Chromatin Assembly Factor 1) et Hir (Histone Regulator), deux protéines chaperons capables de réassembler les histones, s’associent aux sites de cassures doubles brins méiotiques lors de la recombinaison. L’absence de CAF-1 et Hir n’a pas d’effet sur la progression et la formation de CO. Cependant, par des études de recombinaison sur l’ensemble du génome, j’ai pu observer que l’absence de CAF-1 tend à réduire l’interférence des CO. Ce résultat suggère que CAF-1 pourrait être un des facteurs régulant la réparation au cours de la recombinaison méiotique. Pour finir, je me suis aussi intéressée à un troisième chaperon d’histone H3/H4, Asf1. J’ai aussi pu montrer que la délétion d’un autre chaperon Asf1 (Anti-silencing Function 1) entraîne des défauts de progression méiotique et de formation des spores.Ce travail aide à mieux comprendre l'impact de la chromatine sur la réparation de la méiose et le rôle des facteurs d'assemblage de la chromatine. / During meiosis, hundreds of programmed double strand breaks (DSB) are generated and repaired by homologous recombination. Meiotic DSB can be repaired by two major alternative pathways, which generate either crossing-over (CO) or non-crossing-over (NCO) products. The choice between the two repair pathways is tightly controlled to ensure sufficient and accurate CO formation. The chromatin environment could play a crucial role in this process that has not been elucidated yet. Little information is available about the importance of chromatin factors for meiotic recombination. The aim of my PhD was to study chromatin factors necessary for chromatin dynamic during meiotic recombination. I have shown that CAF-1 (Chromatin Assembly Factor 1) and Hir (Histone Regulator), two chaperone proteins that are able to incorporate histones into chromatin, associate with DSB sites during meiotic recombination. CAF-1 and Hir deletion have no effect on the outcome of meiosis and CO formation. However, by genome-wide recombination studies, I have observed that the absence of CAF-1 histone chaperone results in a slight decrease in CO interference. The result suggests that CAF-1 could be one of the factors regulating DNA repair during meiotic recombination. Finally, I have also studied another H3/H4 chaperone, Asf1 (Anti-silencing Function1). Asf1 deletion gives rise to a defect in meiotic progression and spore formation. This work helps to better understand the impact of chromatin on meiotic repair and the role of chromatin assembly factors.

Chromatine

Méiose

Réparation

Cassures doubles brins

Chaperon d'histones

CAF-1

Double strand breaks

Meiosis

576

La formation des cassures double-brins méiotiques chez l’espèce modèle Arabidopsis thaliana / Meiotic double-strand breaks formation in the plant model Arabidopsis thaliana

Vrielynck, Nathalie

10 June 2016

La méiose est essentielle pour tous les organismes à reproduction sexuée car cette division cellulaire spécialisée conduit à la formation de gamètes. Au cours de la méiose, la formation de bivalents est une étape clé dans la répartition équilibrée des chromosomes homologues. Dans la majorité des espèces, la formation de ces bivalents repose sur le mécanisme de la recombinaison homologue qui est un mécanisme de réparation des cassures double brin (CDB) de l’ADN. En méiose, la cassure est programmée et provoquée par l’action de Spo11. A.thaliana contient deux homologues SPO11-1 et SPO11-2 qui ne sont pas redondants dans la formation des CDB. Spo11 est une protéine apparentée à la sous-unité A des topoVI d’Archaea. Or, les topoVI d’Archaea fonctionnent en hétérotétramère composé de deux sous-unités A et deux sous-unités B pour former une cassure double brin (CDB) mais jusqu'à mon travail de thèse, aucun homologue méiotique de sous unité B n'avait été identifié. Au cours de ma thèse, j’ai caractérisé la fonction méiotique de la protéine MTOPVIB et montré que c’est un homologue structural de la sous-unité B des TopoVI d’Archaea. Par différentes approches, j’ai montré que MTOPVIB est nécessaire à l’hétérodimérisation de SPO11-1 avec SPO11-2 et je propose que chez A. thaliana, un complexe catalytique de type TopoVI composé de MTOPVIB, SPO11-1, et SPO11-2 est nécessaire à la formation des CDB méiotiques. Chez A. thaliana, en plus de SPO11-1, SPO11-2 et MTOPVIB, quatre autres protéines sont nécessaires à la formation des CDB : PRD1, PRD2, PRD3 et DFO. Par des approches double hybride, j’ai analysé le réseau d’interaction entre ces protéines de « cassure ». Les résultats suggèrent que ces protéines interagiraient au sein d’un « super » complexe essentiel à la formation des CDB méiotiques. / Meiosis is an essential step in sexual reproduction because it leads to the formation of haploid gametes. During meiosis, the formation of bivalents is a key step for the balanced chromosome distribution. In most species, the formation of bivalents lies on the mechanism of homologous recombination that is a repair mechanism for double stranded DNA breaks (DSB). In meiosis, DSB formation is programmed and provoked by the action of Spo11. A.thaliana contains two SPO11-1 and SPO11-2 counterparts which are not redundant in the formation of DSB. Spo11 is related to the A subunit of Archaea topoVI. However, Archaea topoVI operate through a heterotetramer composed of two A subunits and two B subunits but until my thesis work, no meiotic homolog of the B subunit had been identified. During my thesis, I characterized the meiotic function of the new protein MTOPVIB and showed that it shares structural similarities with the B subunit of Archaea TopoVI. Using different strategies, I also demonstrated that MTOPVIB is necessary to the SPO11-1/ SPO11-2 heterodimerization strongly suggesting that in A. thaliana, a catalytic TopoVI like complex is necessary for the formation of meiotic DSB. In addition to SPO11-1, SPO11-2, and MTOPVIB, four other proteins are necessary for the formation of meiotic DSB in A. thaliana : PRD1, PRD2, PRD3 and DFO. By yeast two hybrid approach, I analysed the interaction network between the "DSB" proteins. The results suggest that these proteins could act in a "super" complex which would be essential to the formation of DSBs.

Méiose

ADN

SPO11

Cassure double brin

Complexe topoVI

Meiosis

DNA

SPO11

Double strand break

TopoVI complex

Impact of nuclear organization and chromatin structure on DNA repair and genome stability / Impact de l'organisation du noyau et de la structure de la chromatine sur la réparation de l'ADN et la stabilité du génome

Batté, Amandine

29 June 2016

L’organisation non-aléatoire du noyau des cellules eucaryotes et la compaction de l’ADN en chromatine plus ou dense peuvent influencer de nombreuses fonctions liées au métabolisme de l’ADN, y compris la stabilité du génome. Les cassures double-brin sont les dommages à l’ADN les plus néfastes pour la cellule. Pour préserver l’intégrité de leur génome, les cellules eucaryotes ont développé des mécanismes de réparation des cassures double-brin qui sont conservés de la levure à l’homme. Parmi ceux-ci, la recombinaison homologue utilise une séquence homologue intacte présente ailleurs dans le génome et peut se diviser en deux sous voies de réparation. La conversion génique transfère l’information génétique d’une molécule à son homologue, tandis que le Break Induced Replication (BIR) établit une fourche de réplication qui peut procéder jusqu’à la fin du chromosome.Mon travail de thèse s’est attaché à caractériser la contribution du statut chromatinien et de l’organisation tridimensionnelle du génome à la réparation des cassures double-brin. L’organisation du noyau de la levure S. cerevisiae ainsi que la propagation de l’hétérochromatine au niveau des régions subtélomériques peuvent être modifiées via la surexpression des protéines Sir3 et sir3A2Q. Nous avons montré que le groupement des télomères accroit la conversion génique entre deux séquences subtélomériques, soulignant le rôle clé de la proximité spatiale et de la recherche d’homologie. Nous avons également constaté que la présence d’hétérochromatine au niveau du site de cassure limite la résection, ce qui permet une disparition plus lente des extrémités, qui resteraient disponibles plus longtemps pour réaliser la recherche d’homologie et achever la réparation. Enfin, nous avons observé que la présence d’hétérochromatine au site donneur diminue l’efficacité de recombinaison et qu’elle doit moduler une étape commune aux deux voies de réparation, à savoir l’invasion de brin. Ces travaux nous ont permis de décrire de nouvelles voies de régulation de la réparation de l’ADN. / The non-random organization of the eukaryotic cell nucleus and the folding of genome in chromatin more or less condensed can influence many functions related to DNA metabolism, including genome stability. Double-strand breaks (DSBs) are the most deleterious DNA damages for the cells. To preserve genome integrity, eukaryotic cells thus developed DSB repair mechanisms conserved from yeast to human, among which homologous recombination (HR) that uses an intact homologous sequence to repair a broken chromosome. HR can be separated in two sub-pathways: Gene Conversion (GC) transfers genetic information from one molecule to its homologous and Break Induced Replication (BIR) establishes a replication fork than can proceed until the chromosome end.My doctorate work was focused on the contribution of the chromatin context and 3D genome organization on DSB repair. In S. cerevisiae, nuclear organization and heterochromatin spreading at subtelomeres can be modified through the overexpression of the Sir3 or sir3A2Q mutant proteins. We demonstrated that reducing the physical distance between homologous sequences increased GC rates, reinforcing the notion that homology search is a limiting step for recombination. We also showed that heterochromatinization of DSB site fine-tunes DSB resection, limiting the loss of the DSB ends required to perform homology search and complete HR. Finally, we noticed that the presence of heterochromatin at the donor locus decreased both GC and BIR efficiencies, probably by affecting strand invasion. This work highlights new regulatory pathways of DNA repair.

Cassure double-Brin

Recombinaison

Chromatine

Organisation nucléaire

Double-Strand break

Recombination

Chromatin

Nuclear organization

UBC13-Mediated Ubiquitin Signaling Promotes Removal of Blocking Adducts from DNA Double-Strand Breaks / UBC13を介したユビキチン経路によるDNA二重鎖切断端の付加体除去の促進

Akagawa, Remi

23 September 2020

付記する学位プログラム名: 充実した健康長寿社会を築く総合医療開発リーダー育成プログラム / 京都大学 / 0048 / 新制・課程博士 / 博士(医学) / 甲第22730号 / 医博第4648号 / 新制||医||1046(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 遊佐 宏介, 教授 溝脇 尚志, 教授 篠原 隆司 / 学位規則第4条第1項該当 / Doctor of Medical Science / Kyoto University / DFAM

UBC13

blocking adducts

ionizing radiation

DNA double-strand breaks

TopoisomeraseⅡ

490