Chromatin structure and DNA repair / Etude de la structure de la chromatine dans la réparation de I'ADN

Hoffbeck, Anne-Sophie

25 October 2013

Notre génome est continuellement endommagé par des agents provoquant des lésions de l’ADN. Les cassures doubles brins de l’ADN (CDBs) sont les lésions les plus dangereuses. En effet, une CDB mal réparée peut mener à des aberrations de l’ADN pouvant conduire à l’apparition d’un cancer. Dans le but d’éviter les effets délétères des CDBs, nos cellules ont développé une voie de signalisation, nommée réponse aux dommages de l’ADN (RDA), permettant la détection des cassures et l’activation des points de contrôle du cycle cellulaire afin d’arrêter le cycle pendant la réparation des CDBs. Une des caractéristiques principales de la RDA est l’accumulation d’un grand nombre de facteurs sur l’ADN autour de la cassure, formant un foyer visible en microscopie. Cependant, l’efficacité de réparation de l’ADN est entravée par la structure condensée de la chromatine environnante. Les mécanismes de réparation de l’ADN surmontent ce problème en recrutant de nombreuses protéines permettant le réarrangement de la chromatine afin de faciliter la réparation. Le but de mon travail de thèse est d’identifier de nouvelles protéines impliquées dans le remodelage de la chromatine autour des CDBs. D’une part nous avons pour but d’identifier le protéome complet d’un foyer de réparation de l’ADN grâce à la technique PICh (Proteomics of Isolated Chromatin loci). D’autre part, nous étudions le rôle de l’oncoprotéine SET/TAF-1β, que nous avons identifié lors d’un criblage siRNA réalisé dans le but de découvrir de nouveaux facteurs chromatiniens impliqués dans la réparation des CDBs. / Various DNA damaging agents, that can cause DNA lesions, assault constantly our genome. The most deleterious DNA lesions are the breaks occurring in both strands of DNA (Double stand breaks: DSBs). Inefficient repair of DSBs can lead to aberrations that may induce cancer. To avoid these deleterious effects of DSBs, cells have developed signalling cascades which entail detection of the lesions and spreading of the signal that leads to arrest in cell cycle progression and efficient repair. A major characteristic of DNA damage response (DDR) is the accumulation of a vast amount of proteins around the DSBs that are visible in the cell as DNA damage foci. However, efficient DNA repair is hampered by the fact that genomic DNA is packaged into chromatin. The DNA repair machinery overcomes this condensed structure to access damaged DNA by recruiting many proteins that remodel chromatin to facilitate efficient repair. The aim of my PhD work is to identify novel proteinsinvolved in the DDR and/or the remodelling of chromatin surrounding DSBs. On one hand, we take advantage of the PICh (Proteomics of Isolated Chromatin loci) technique and we aim to identify the entire proteome of DNA repair foci. On the other hand, we study the role of the oncogene SET/TAFIβ, a major hit of a siRNA screen performed to identify novel chromatin related proteins that play role in repair of DSBs.

Réponse aux dommages de l’ADN

Cassure double brin

Réparation de l’ADN

PICh

Recombinaison homologue

Stress réplicatif

SET

TAF-Iβ

DNA damage response

Double strand break

DNA repair

PICh

Homologous recombination

Replication stress

SET

TAF-Iβ

572.8

O papel de RhoA e Rac1 GTPases nas respostas celulares após danos no DNA induzidos por radiação ionizante gama / The role of RhoA and Rac1 GTPases in cellular responses after DNA damage induced by ionizing gamma radiation

Juliana Harumi Osaki

18 June 2015

O mecanismo pelo qual uma célula responde a algum dano no seu material genético é extremamente importante. Isto ocorre pela rápida ativação da maquinaria de reparo de danos no DNA, a qual é composta por uma rede intrincada de sinalização proteica, culminando no reparo do DNA; porém se o dano for irreparável ocorre ativação de mecanismos de morte celular. RhoA,e Rac1 pertencem a família das pequenas proteínas sinalizadoras Rho GTPases, as quais atuam como interruptores moleculares ciclando entre estado ativo (ligada a GTP) e inativo (ligada a GDP). Os componentes desta família estão relacionados ao controle dos mais diversos processos celulares como, por exemplo, remodelamento do citoesqueleto, migração, adesão, endocitose, progressão do ciclo celular e oncogênese. No entanto, apesar das proteínas Rho GTPases estarem envolvidas em um amplo espectro de atividades biológicas, há poucas informações sobre seu papel na manutenção da integridade genômica quando células são submetidas a algum agente genotóxico. Para investigar o envolvimento das GTPases RhoA e Rac1 nas respostas de células submetidas a radiação gama, foram gerados, a partir de células de carcinoma de cervix humano - HeLa, sublinhagens clonais mutantes de RhoA e Rac1 expressando exogenamente RhoA constitutivamente ativa (HeLa-RhoA V14), RhoA dominante negativa (HeLa-RhoA N19), Rac1 constitutivamente ativa (HeLa-Rac1 V12) e Rac1 dominante negativa (HeLa-Rac N17). Após estas linhagens celulares serem expostas a diferentes doses de radiação gama, observamos que ambas GTPases, RhoA e Rac1, são ativadas em resposta aos efeitos da radiação. Além disso, a modulação da atividade destas enzimas, através das mutações, levou a uma alteração das respostas celulares frente aos danos no DNA, como uma redução da capacidade de reparar quebras simples e duplas nas fitas do DNA. Por outro lado, a deficiência de RhoA ou Rac1 GTPase levou a uma redução da ativação de Chk1 e Chk2 ou da fosforilação da histona H2AX, respectivamente, prejudicando os mecanismos de detecção de danos no DNA e levando as células a permanecerem mais tempo nos pontos de checagem G1/S e/ou G2/M do ciclo celular. Esses fatores contribuíram de modo expressivo para a redução da proliferação e sobrevivência celular levando as células à morte. Por fim, ensaios celulares de reparo de danos de um DNA exógeno através de mecanismos de Recombinação Homóloga (HR) e Recombinação Não-Homóloga de extremidades (NHEJ), demonstraram que a inibição da atividade de RhoA reduz significativamente a eficiência de ambas vias de reparo. Desta maneira, este trabalho demonstra e reforça a existência de mais um viés de atuação das pequenas GTPases RhoA e Rac1, agora em células HeLa, nas respostas celulares aos danos induzidos por exposição a radiação gama, modulando a sobrevivência, proliferação e indiretamente modulando resposta ao reparo do DNA através da via de Recombinação Homóloga e Não-Homóloga / The mechanism by which a cell responds to DNA damage is extremely important. This occurs by a quick activation of the DNA damage repair machinery, which consists of an intricate protein signaling network culminating in DNA repair. But if the damages are irreparable occurs there is activation of cell death mechanisms. RhoA and Rac1 belong to family of small Rho GTPases, signaling proteins that act as molecular switches cycling between the active state (GTP-bound) and inactive state (GDP-bound). Members of this family are implicated in the control of diverse cellular process such as cytoskeletal remodeling, migration, adhesion, endocytosis, cell cycle progression, and oncogenesis. However, despite Rho proteins are involved in a broad spectrum of biological activities, there is just a few information about their roles in the maintenance of genomic integrity, that is, when the cells are subjected to some kinf of genotoxic agent. To investigate the involvement of the GTPases RhoA and Rac1 in cellular responses to gamma radiation, we generated from human cervix carcinoma cells - HeLa, clonal sublines of RhoA and Rac1 mutants, exogenous and stably expressing the constitutively active RhoA (HeLa-RhoA V14), the dominant negative RhoA (HeLa-RhoA N19), the constitutively active Rac1 (HeLa-Rac1 V12) and the dominant negative Rac1 (HeLa-Rac1 N17). After all these cell lines have been exposed to different doses of gamma radiation, we found that both GTPases, RhoA and Rac1, are activated in response to the radiation effects. Furthermore, the modulation of two enzymes activity, by using the mutant clones, led to a change in cellular responses to the DNA damage, as the reduction in the capacity of repairing DNA single and double strand breaksr. On the other hand, the deficiency of RhoA or Rac1 GTPase led to a reduction of Chk1 and Chk2 activation, or on the phosphorylation of histone H2AX, respectively, hindering the mechanisms of DNA damage detection and arresting cells in the G1/S and/or G2/M checkpoints of cell cycle. These factors significantly contributed to the reduction of cell proliferation and survival, leading cells to death. Finally, cellular assays of DNA damage repair of exogenous DNA by Homologous Recombination (HR) and Non-Homologous End Joining (NHEJ), demonstrated that RhoA inhibition significantly reduced the repair efficiency of both pathways. Thus, this work demonstrates and reinforces the existence of other biological functions of small GTPases RhoA and Rac1 in HeLa cells, by regulating cellular responses to DNA damage induced by exposure to gamma radiation, modulating the survival, proliferation and indirectly modulating the response to DNA damage repair pathway through the Homologous Recombination and Non-Homologous Recombination

Integridade e estabilidade genômica

Pequenas Rho GTPases

Rac1

Radiação gama

Resposta a danos e reparo no DNA

RhoA

Sinalização celular

Cell signaling

DNA damage response and repair

Gamma radiation

Genomic integrity and stability

Rac1

RhoA

Small Rho GTPase

<em>PALB2</em> and <em>RAP80</em> genes in hereditary breast cancer predisposition

Nikkilä, J. (Jenni)

29 January 2013

Abstract Around 5–10% of all breast cancers stem from a strong hereditary predisposition to the disease. Mutations in currently known breast cancer predisposing genes, however, account for only 25–30% of all hereditary breast cancer cases, BRCA1 and BRCA2 being the two major ones. Since BRCA1 and BRCA2 participate in the DNA damage response, mutations in other genes, such as PALB2 and RAP80, which are involved in these pathways, may also predispose to breast tumours. Therefore, the aim of this study was to evaluate variations of the human PALB2 and RAP80 genes as novel potential candidates for breast cancer susceptibility and to further characterize the role of PALB2-deficiency in cancer development. A mutation, c.1592delT, was identified in PALB2 at an elevated frequency among breast cancer patients (0.9%) compared to controls (0.2%) (P&#160;= &#160;0.003, OR 3.94, 95% CI 1.5–12.1). Among familial cases the frequency was even higher (2.7%). This mutation represents a genuine loss-of-function mutation since its protein product showed significantly decreased BRCA2-binding affinity and could neither support homologous recombination nor restore crosslink repair in PALB2-deficient cells. Heterozygous PALB2 c.1592delT carriers displayed haploinsufficiency of PALB2 marked by aberrant DNA replication and DNA damage response that led to a significant increase in genomic instability. As the tumours were negative for loss of heterozygosity at this chromosomal locus, these findings provide a mechanism for the early stages of breast cancer development in PALB2 c.1592delT carriers. Palb2 was also found to play a critical role in early mouse development. As in Brca1/2-deficient embryos, homozygous inactivation of Palb2 resulted in embryonic lethality due to mesoderm differentiation and cell proliferation defects. The phenotypic similarity of Palb2 and Brca1/2-deficient mice further supports the close functional relationship shown in vitro for these proteins. A novel mutation, delE81, was identified in RAP80 in one out of 112 breast cancer families, and in one patient diagnosed with bilateral breast cancer out of 503 unselected breast cancers. The resultant delE81 protein displayed significantly reduced ubiquitin binding and double-strand break (DSB) localization. Furthermore, it impaired the recruitment of the whole BRCA1-A complex to the site of DSBs, thus compromising BRCA1-mediated DNA damage response signalling. Although the mutation is quite rare, the current results indicate that the RAP80 delE81 defect is biologically relevant and is likely associated with a hereditary predisposition to breast cancer. / Tiivistelmä Arviolta 5–10 % rintasyöpätapauksista aiheutuuu merkittävästä perinnöllisestä alttiudesta sairauteen. Mutaatiot tähän mennessä tunnistetuissa rintasyövän alttiusgeeneissä, joista BRCA1 ja BRCA2 ovat tärkeimmät, selittävät kuitenkin vain 25–30 % kaikista perinnöllisistä rintasyöpätapauksista. Tämän tutkimuksen tarkoituksena on arvioida PALB2- ja RAP80-geenien mahdolliset vaikutukset rintasyöpäalttiuteen, sekä määrittää tarkemmin PALB2:n vaikutus syövän kehitykseen. PALB2:sta löydettiin mutaatio, c.1592delT, jota esiintyi merkittävästi enemmän rintasyöpäpotilailla (0,9&#160;%) kuin kontrollihenkilöillä (0,2&#160;%) [P&#160;= &#160;0.003, OR 3.94, 95&#160;% CI 1.5–12.1]. Kaikista yleisimmin geenimuutos esiintyi perinnöllisten ritasyöpätapausten joukossa (2,7&#160;%). Mutaatio aiheuttaa toiminnallisesti viallisen proteiinin, joka sitoutuu BRCA2:n kanssa normaalia heikommin, eikä se pysty kunnolla toimimaan homologisessa rekombinaatiossa tai ristikkäiden DNA-virheiden korjauksessa. Heterotsygoottisen PALB2 c.1592delT-mutaation aiheuttaa PALB2-geenin haploinsuffisienssi joka ilmentyy kantajien soluissa epänormaalina DNA:n kahdentumisena ja DNA-vauriovasteena, jotka johtavat merkittävästi kohonneeseen genomin epävakaisuuteen. Jo kyseiset toiminnalliset puutteet näyttävät tarjoavan pätevän selityksen PALB2 c.1592delT kantajien merkittävästi suurentuneelle rintasyöpäriskille ja lienee myös syy siihen, ettei potilaiden kasvaimissa havaittu normaalin vastinaleelin menetystä. Palb2:lla on keskeinen rooli hiiren alkiokehityksessä. Kuten Brca1/2-puutteellisissa alkioissa, myös homotsygoottinen Palb2-inaktivaatio aiheuttaa alkioiden enneaikaisen kuoleman, joka aiheutuu puutteista mesodermin erilaistumisessa ja hidastuneesta solujen kasvussa. Palb2- ja Brca1/2-puuttellisten hiirien samankaltaisuus vahvistaa ennestään näiden proteiinien toiminnallista yhteyttä, joka on osoitettu jo aikaisemmin laboratorio-oloissa. RAP80-geenistä löydettiin uusi mutaatio, delE81, yhdestä 112 tutkitusta rintasyöpäperheestä. Kyseinen muutos nähtiin myös yhdessä molemminpuoliseen rintasyöpään sairastaneessa potilaassa valikoimattomassa 503 tapauksen kattavasta aineistosta. Mutatoitunut proteiinituote vähensi huomattavasti DNA-vauriovastekompleksin kykyä sitoutua ubikitiiniin ja paikallistua DNA-kaksoisjuostekatkoksille. Ennen kaikkea mutaatio heikensi BRCA1-A kompleksin kuljetuksen DNA-vauriopaikalle, vaarantaen BRCA1-välitteisen DNA-vauriovasteen. Harvinaisuudesta huolimatta nämä tutkimustulokset osoittavat RAP80 delE81 vaikutuksen olevan biologisesti merkittävä. Kyseinen synnynnäinen RAP80-geenimuutos altistaa mitä todennäköisimmin kantajansa rintasyövälle.

DNA damage response

DNA repair

DNA replication

PALB2

RAP80

genetic predisposition to breast cancer

haploinsufficiency

mouse embryonal development failure

DNA-korjaus

DNA-replikaatio

DNA-vauriovaste

PALB2

RAP80

haploinsuffisienssi

perinnöllinen rintasyöpäalttius

Role of PML in nucleolar functions / Role of PML in nucleolar functions

Kučerová, Alena

January 2016

Promyelocytic leukemia protein (PML) is a tumour suppressor which is frequently downregulated in human tumours. PML plays a role in many cellular processes including DNA damage response, senescence and apoptosis and is mainly localized in special structures called PML nuclear bodies (PML NBs). The nucleolus is a key nuclear compartment, where transcription of ribosomal DNA and biogenesis of ribosomes take place. The nucleolus is also called a stress sensor because of its role, for instance, in stabilization of tumour suppressor p53. Localization of PML to the nucleolar periphery appears to be prominent after disturbance of nucleolar functions - for example inhibition of rRNA transcription or processing. Thus the relationship between the nucleolus and PML nuclear bodies may be important for cellular response to stress. However, the role of PML nucleolar associations in nucleolar function including mechanism of formation of these structures remain unclear. Here we characterised PML nucleolar structures and mechanism of their formation. We showed that formation of PML nucleolar structures is not caused by replication stress, is not dependent on any specific phase of cell cycle and is not caused by DNA damage response but is induced by topological stress due to inhibition of toposiomerase function....

Hereditary predisposition to breast cancer – with a focus on <em>AATF</em>, <em>MRG15</em>, <em>PALB2</em>, and three Fanconi anaemia genes

Haanpää, M. (Maria)

27 May 2014

Abstract Around 5−10% of all breast cancer cases are estimated to result from a strong hereditary predisposition to the disease. However, mutations in the currently known breast cancer susceptibility genes account for only 20−30% of all familial cases. Additional factors contributing to the pathogenesis of breast cancer, therefore, await discovery. Aims of this study were to evaluate variations of the AATF and MRG15 genes as novel potential candidates for breast cancer susceptibility, to further examine the prevalence of the cancer-related PALB2 c.1592delT mutation among BRCA-negative high-risk breast cancer families counselled at the Department of Clinical Genetics, Oulu University Hospital, to identify Finnish Fanconi anaemia patients complementation groups as well as causative mutations, and to evaluate the potential role of these mutations in breast cancer susceptibility. The analysis of 121 familial breast cancer cases revealed altogether seven different sequence changes in the AATF gene. However, none of them were considered pathogenic, suggesting that germline mutations in AATF are rare or absent in breast cancer patients. Investigation of the MRG15 gene among familial breast cancer cases revealed seven previously unreported variants, but in silico analyses revealed that none of these variants appeared to modify the function of MRG15. The results suggest that MRG15 alterations are unlikely to be significant breast cancer susceptibility alleles. A previously identified pathogenic PALB2 mutation, c.1592delT, was identified in three patients from a cohort of 62 high-risk BRCA1/2-negative breast cancer patients from the Department of Clinical Genetics. PALB2 c.1592delT mutation testing should thus be a routine part of the genetic counselling protocol, particularly for BRCA1/2-negative high-risk breast cancer patients. Investigation of the complementation groups of Finnish Fanconi anaemia patients revealed a total of six different causative mutations. These mutations were examined further by analysing their prevalence in large cohorts of breast (n=1840) and prostate (n=565) cancers. However, no significant association emerged between cancer predisposition and these FA mutations. / Tiivistelmä Arviolta 5−10 prosenttia kaikista rintasyöpätapauksista aiheutuu merkittävästä perinnöllisestä alttiudesta sairauteen. Tällä hetkellä tiedossa olevien rintasyövälle altistavien geenivirheiden ajatellaan kuitenkin selittävän vain noin 20−30 prosenttia kaikista perinnöllisistä tapauksista. On todennäköistä, että uusia tekijöitä, jotka osallistuvat rintasyövän patomekanismiin, on vielä löytymättä. Tämän tutkimuksen tarkoituksena oli arvioida AATF- ja MRG15-geeneissä esiintyvien muutosten mahdollista vaikutusta rintasyöpäalttiuteen, tutkia tarkemmin PALB2 c.1592delT -mutaation esiintymistä BRCA-mutaationegatiivisten korkean rintasyöpäriskin potilaiden joukossa (perinnöllisyyspoliklinikka, Oulun yliopistollinen sairaala) ja määrittää suomalaisten Fanconi-anemiapotilaiden komplementaatioryhmät, sairauden taustalla olevat mutaatiot sekä tutkia näihin mutaatioihin mahdollisesti liittyvää rintasyöpäriskiä. 121 familiaalisen rintasyöpätapauksen analyysissä löytyi yhteensä seitsemän erilaista sekvenssimuutosta AATF-geenissä. Näistä yksikään ei kuitenkaan ollut selvästi patogeeninen. Tuloksen perusteella perinnölliset rintasyövälle altistavat muutokset AATF-geenissä ovat joko erittäin harvinaisia tai niitä ei esiinny lainkaan. MRG15-geenin mutaatioanalyysissä havaittiin seitsemän aikaisemmin raportoimatonta muutosta, mutta in silico -analyysien perusteella millään muutoksista ei ole vaikutusta MRG15-proteiinin toimintaan. Tulosten perusteella on epätodennäköistä, että MRG15-geenin muutokset olisivat merkittäviä rintasyövälle altistavia muutoksia. Jo aiemmin patogeeniseksi todettu PALB2 c.1592delT -mutaatio löydettiin kolmelta niistä perinnöllisyyspoliklinikan korkean syöpäriskin 62 potilaasta, jotka olivat BRCA1/2-geenitestauksessa saaneet normaalin tuloksen. Tulostemme perusteella PALB2 c.1592delT -mutaatiotestaus tulisi Suomessa ottaa osaksi perinnöllisyyspoliklinikoiden tarjomaa tutkimusprotokollaa. Suomalaisten Fanconi-anemiapotilaiden komplementaatioryhmiä selvittävässä tutkimuksessa identifioitiin yhteensä kuusi erilaista tautia aiheuttavaa mutaatiota. Näiden muutosten esiintymistä tutkittiin myös laajoissa rinta- (n=1840) ja eturauhassyöpäaineistoissa (n=565). Tilastollisesti merkittävää assosiaatiota ei kuitenkaan todettu suomalaisten FA-mutaatioiden ja syöpäalttiuden välillä.

DNA damage response

DNA repair

Fanconi anaemia

breast cancer

genetic predisposition to disease

germline mutation

DNA-korjaus

DNA-vauriovaste

Fanconin anemia

ituradan mutaatio

perinnöllinen rintasyöpäalttius

rintasyöpä

AATF

MRG15

PALB2

Analyse des dommages à l'ADN induits par la toxine CDT et de leur réparation / Analysis of DNA damage induced by the CDT toxin and of the DNA repair mechanisms involved

Bezine, Elisabeth

23 November 2015

La Cytolethal Distending Toxin (CDT) est un facteur de virulence produit par de nombreuses bactéries pathogènes Gram négatives. Sa production est associée à différentes pathologies, dont le développement de cancers. Un lien de causalité a été établi entre dommages à l’ADN, mutagénèse et cancérogenèse. Or, différentes études ont classé CDT dans la famille des génotoxines bactériennes. L’action génotoxique de CDT repose sur l’activité de sa sous-unité catalytique CdtB, connue pour induire des cassures double-brin (CDBs) de l’ADN génomique eucaryote. Cependant, des travaux de l’équipe ont montré qu’à des doses 1000 fois plus faibles que celles utilisées dans la littérature, CDT induit des dommages primaires (probablement de type cassure simple-brin), qui dégénèrent en CDB lors de la phase S. Afin de mieux documenter ce modèle, nous avons étudié ici les systèmes de réparation impliqués dans la réponse aux dommages à l’ADN induits par CDT. Nous avons ainsi confirmé l’importance des voies de réparations des CDBs (Homologous Recombinaison et Non-Homologous End-Joining). Nous avons également montré que le Nucleotide Excision Repair, impliqué dans la réparation des adduits à l’ADN, n’est pas impliqué dans la prise en charge des dommages induits par CDT. En revanche, nous avons démontré, pour la première fois, l’implication de systèmes de réparation de dommages plus précoces, comme le Single-Strand Break Repair et la voie de l’Anémie de Fanconi. Pour finir, afin de mieux caractériser ces dommages et leur induction, nous avons initié des travaux visant à étudier, in vitro, l’activité catalytique de CdtB. Dans ce but, différents mutants catalytiques ont été générés, purifiés, et leur activité nucléase a été testée. Une activité nucléase similaire entre les CdtB sauvages et mutantes a été obtenue lors d’un test in vitro (digestion d’un plasmide super-enroulé). Cependant, un test cellulaire (expression nucléaire en cellules eucaryotes de la sous-unité CdtB sauvage ou mutante) indique bien la perte de l’activité nucléase de la sous-unité mutante. Nos résultats montrent donc l’importance de tester les différentes sous-unités dans différents contextes. En conclusion, notre travail conforte les données selon lesquelles CDT induit des CSB, et non des CDB directes de l’ADN. De plus, notre travail a permis d’éclaircir les processus cellulaires activés dans la cellule hôte, suite aux dommages à l’ADN induits par CDT. / The Cytolethal Distending Toxin (CDT) is a virulence factor produced by many pathogenic gram-negative bacteria, its production being associated to various diseases, including tumorigenesis. A causal relationship has been established between DNA damage, mutagenesis and cancerogenesis. Different studies classified CDT among the bacterial genotoxins. The CDT-related pathogenicity relies on the catalytic subunit CdtB action, shown to induce double-strand breaks (DSB) on the host genomic DNA. Previously, our team showed that, at doses 1000 times lower than those used in the literature, CDT probably induces single-strand breaks that degenerate into DSB during S-phase. To document this model, we studied the repair systems involved in host-cell in response to CDT-induced DNA damage. Since various repair pathways allow cells to respond different type of DNA damage, we speculated that non-DSB repair mechanisms might contribute to the cellular resistance to CDT-mediated genotoxicity. First, we confirm that HR is involved in the management of CDT-induced lesions, but also Non Homologous End Joining, the second major DSB repair mechanism. Next we show that nucleotide excision repair, involved in adducts repair, is not important to take care of CDT-induced DNA damage, whereas base excision repair impairment sensitizes CDT-treated cells, suggesting that CDT induce single-strand breaks. Moreover, we demonstrate for the first time the involvement and the activation of the Fanconi Anemia repair pathway in response to CDT. Finally, to better characterize CDT-induced damage, we initiate experiments to study CdtB nuclease activity in vitro. For this, different CdtB mutants have been generated, purified and their nuclease activity tested. A similar nuclease activity has been obtained for the wt or mutant CdtB in an in vitro assay (digestion of a supercoiled plasmid). However, a cell assay (nuclear expression of CdtB in eukaryotic cells) confirms the loss of activity for the mutant subunit. Our results thus indicate the importance to test the CdtB subunit in different context. To conclude, our work reinforces a model where CDT induces single-strand damage and not direct DSB. This also underlines the importance of cell proliferation to generate DSB and sheds light on the activated host-cell systems, after CDT-induced DNA damage.

Cytolethal Distending Toxin

Génotoxine bactérienne

Dommages à l'ADN

Réponse aux dommages à l'ADN

Nucléase

Cytolethal Distending Toxin

Bacterial genotoxin

DNA damage

DNA damage response

Eukaryotic DNA repair mechanisms

Nuclease

Physiological And Exogenous Means of Regulating DNA Damage Response : Insights into Mechanisms of DNA Repair And Genomic Instability

Sebastian, Robin

January 2016

Maintenance of genomic integrity with high fidelity is of prime importance to any organism. An insult which may result in compromised genome integrity is prevented or its consequences are monitored by advanced cellular networks, collectively called the DNA damage response (DDR). Various DNA repair pathways, which are part of DDR, constantly correct the genome in the event of any undesirable change in the genetic material and prevent the transmission of any impairment to daughter cells. Non homologous DNA end joining (NHEJ) is the predominant DNA repair pathway associated with DDR in higher eukaryotes, correcting double-strand breaks (DSBs). Microhomology mediated end joining (MMEJ), an alternate mechanism to NHEJ also exists in cells, which is associated with erroneous joining of broken DNA, leading to mutagenesis. DDR is of paramount importance in cellular viability and therefore, any defects in DDR or the imbalance of repair pathways contribute to mutations, cellular transformations and various neurodegenerative and congenital abnormalities. Here, we investigate the DDR via NHEJ and MMEJ pathways during embryonic development in mice as well as in presence of an environmental pollutant, Endosulfan, in order to understand how physiological and exogenous factors condition the balance of repair pathways. Among various classes of pesticides known to cause side effects, organochlorine pesticides (OCPs) lead the list, possessing high transport potential, and a variety of toxic and untoward health effects. Endosulfan is a widely used organochlorine pesticide and is speculated to be detrimental to human health. However, very little is known about mechanism of its genotoxicity. Using in vivo and ex vivo model systems, we showed that exposure to Endosulfan induced reactive oxygen species (ROS) in a concentration dependent manner. Using an array of assays and equivalents of sub-lethal concentrations comparable to the detected level of Endosulfan in humans living in active areas of exposure, we demonstrated that ROS production by Endosulfan resulted in DNA double-strand breaks in mice, rats and human cells. In mice, the DNA damage was predominantly detected in type II pneumocytes of lung tissue; spermatogonial mother cells and primary spermatids of testes. Importantly, Endosulfan-induced DNA damage evoked DDR, which further resulted in elevated levels of classical NHEJ. However, sequence analyses of NHEJ junctions revealed that Endosulfan treatment resulted in extensive processing of broken DNA, culminating in increased and long junctional deletions, thereby favouring erroneous repair. We also find that exposure to Endosulfan led to significantly increased levels of MMEJ, which is a LIGASE III dependent, alternative, non classical repair pathway, encompassing long deletions and processing of DNA. Further, we show that the differential expression of proteins following exposure to Endosulfan correlated with activation of alternative DNA repair. At the physiological level, using mouse model system, we showed that exposure to Endosulfan affected physiology and cellular architecture of organs and tissues. Among all organs, damage to testes was extensive and it resulted in death of different testicular cell populations. We also found that the damage in testes resulted in qualitative and quantitative defects during spermatogenesis in a time dependent manner, increasing epididymal ROS levels and affecting sperm chromatin integrity. This further culminated in reduced number of epididymal sperms and actively motile sperms, which finally resulted in reduced fertility in male but not in female mice. Repair of DSBs is important for maintaining genomic integrity during the successful development of a fertilized egg into a whole organism. To date, the mechanism of DSB repair in post implantation embryos has been largely unknown except for the differential requirement of DNA repair genes in the course of development. These studies relied on null mutation analysis of animal phenotypes and therefore a quantitative understanding of repair pathways was absent. In the present study, using a cell free repair system derived from different embryonic stages of mice, we found that canonical NHEJ is predominant at 14.5 day of embryonic development. Interestingly, all types of DSBs tested were repaired by LIGASE IV/XRCC4 and Ku-dependent classical NHEJ. Characterization of end-joined junctions and expression studies further showed evidence for C-NHEJ. Strikingly, we observed non canonical end joining accompanied by DSB resection, dependent on microhomology and LIGASE III in 18.5-day embryos. Further we observed an elevated expression of CtIP, MRE11, and NBS1 at this stage, suggesting that it could act as a switch between classical and microhomology-mediated end joining at later stages of embryonic development. Keeping these observations in mind, we wondered if Endosulfan affected the differential regulation of DDR during development, similar to mice tissues. Upon analysing the effect of endosulfan on NHEJ/MMEJ at above mentioned stages of mouse embryonic development, we found that C-NHEJ efficiency remained low or unaltered while the efficiency of MMEJ was upregulated significantly, perturbing the repair balance during embryo development and hence facilitating mutagenic repair. Thus, our results establish the existence of both classical and non classical NHEJ pathways during the post implantation stages of mammalian embryonic development. Our studies also provide deeper insights into physiological and molecular events leading to male infertility upon Endosulfan exposure and its impact on impairing the differential regulation of DNA repair during embryonic development. Our findings suggest the plasticity of DNA repair pathways in physiological and pathological conditions and provide insights into mechanism of genome instability due to DNA repair imbalance, when exposed to environmental mutagens.

DNA Damage

DNA Repair

Genomic Instability

DNA Damage Response (DDR)

Endosulfan Induced DNA Damage

Genomic Integrity

Non Homologous DNA End Joining (NHEJ)

Reactive Oxygen Species

DNA Repair Pathways

Biochemistry

Buněčná odpověď na protinádorové terapie založené na genotoxickém stresu / Cell response to genotoxic stress-based anti-cancer therapies

Imrichová, Terezie

January 2019

The dissertation deals with a cell response to genotoxic stress, specifically to anti-cancer treatments with a genotoxic mechanism of action. In principle, cells can respond to these perturbing stimuli in several ways: in case of severe DNA damage, they usually undergo apoptosis or enter senescence. In case of minor DNA damage, or upon defective checkpoint mechanisms, they may continue the cell cycle, either with successfully repaired DNA or with mutations of various kind. Thanks to selection pressure, the mutations that provide cells with a certain growth advantage under conditions of continuing genotoxic stress, gradually accumulate and render the tumor treatment-resistant. In my thesis, I focus on several aspects of this whole process. First, I participated in a characterization of a radioresistant and anoikis-resistant population of prostate cancer cells. This population was generated by irradiating cells 35 times by 2 Gy, a regime used in clinics. After this treatment, a population of low-adherent cells emerged that demonstrated increased expression of EMT- and stem cell markers. The low-adherent state of these cells was maintained by Snail signaling and their anoikis resistance by ERK1/2 signaling. Interestingly, after a protracted period of time, these cells were able to re-adhere and...

Untersuchungen zur Funktion des Inhibitor der Apoptose Proteins Survivin in der chromosomalen Stabilität und „DNA Damage Response“ von Tumorzellen

Wiedemuth, Ralf

08 October 2012

Das nur 16,5 kDa große Survivin ist ein bifunktionales Protein, welches eine bedeutende Rolle in zwei wichtigen zellulären Prozessen spielt, der Apoptose und der Mitose. Aufgrund seiner BIR Domäne wird es zu den Inhibitor der Apoptose Proteine (IAP) gezählt. Diese Gruppe an Proteinen interferiert negativ mit der Aktivierung der Caspasen und wirkt somit einer Induktion der Apoptose entgegen. Neben seiner anti-apoptotischen Funktion besitzt das Survivin zudem eine essentielle Rolle bei der Segregation der Chromosomen und während der Zytokinese. In der Mitose bildet Survivin mit Borealin, INCENP und der mitotische Aurora B Kinase den Chromosomalen Passenger Complex (CPC). Das Survivin besitzt zudem eine grosse medizinische Relevanz und gilt als Tumor-assoziertes Antigen, da es zu den Top vier Transkripten zählt, die in einer Vielzahl unterschiedlicher Tumorentitäten überexprimiert werden, aber nicht in Normalgewebe. Diese Überexpression geht einher mit einer erhöhten Resistenz der Tumore gegenüber Chemo- und Strahlentherapie und macht Survivin zu einem idealen molekularen Ziel einer Krebstherapie mittels RNA Interferenz oder spezifischer pharmakologischer Inhibitoren. In einer Vielzahl an Studien, in denen das Survivin-Protein mittels RNAi, dominant negativer Proteine oder „knock out“ des Survivin Genes (BIRC5) aus geschalten wurde, konnte eine Aktivierung des Tumorsuppressorproteins p53, einem wichtigen Mediator der Zellzyklusregulation, beobachtet werden. Bis heute ist es weitgehend unklar, wie eine Aktivierung von p53 nach einem Survivin Verlust erfolgen kann. Zudem stellte sich die Frage, ob eine therapeutische Intervention, welche die Ausschaltung des Survivin-Proteins zum Ziel hat, neben Tumorzellen auch normales Gewebe schädigen kann. Da Tumorzellen sich von normalen Zellen insbesondere dadurch unterscheiden, dass sie Defekte in p53-Signalwegen bzw. eine inaktivierende p53-Mutation oder Gendeletion besitzen, wurde die Auswirkung einer Survivin-Depletion auf p53-positive Tumorzellen und auf isogene Tumorzellen mit ausgeschalteten p53 untersucht. Zu diesem Zweck wurde p53 mittels RNAi in U87-MG und MCF-7 Zellen ausgeschalten und stabile p53-defiziente Zellen generiert. Insgesamt standen für die Untersuchungen mit HCT116, MCF-7 und U87-MG drei Zelllinien unterschiedlichen Ursprungs sowie ihre isogenetischen, aber p53-defizienten Derivate zur Verfügung. Survivin wurde in diesen Zellen durch einen retroviralen Vektor, der für eine shRNA (small hairpin RNA) gegen Survivin codiert, ausgeschalten. Der Verlust an Survivin führte dabei in Wildtyp- als auch in den p53-defizienten Zellen zu Polyploidie, einer gestörten Zytokinese und multipolaren Spindeln. Zusätzlich konnte eine Induktion an p53/p21waf/cip sowie eine erhöhte, p53- und Caspase 3-unabhängige Apoptose festgestelt werden. Es konnte gezeigt werden, dass die Expression an p21waf/cip in Wildtyp-Zellen sowie seines potentiellen Targets Cyclin D1 mit der Zunahme an Polyploidie nach Survivin RNAi korreliert. Allerdings führt die Expression des Cdk Inhbibitors p21waf/cip nur zu einem transienten Arrest der Zellen, da polyploide, Survivin-depletierte Zellen BrdU inkorporierten und dadurch proliferierten. Zudem wird zum ersten Mal eine ATM/ATR abhängige „DNA Damage Response“ (DDR) in Survivin-depletierten p53-defzienten und Wildtyp Zellen beschrieben, die zu einer Phosphorylierung und Stabilisierung von p53 führt. Sky-Analysen bestätigten numerische als auch schwere chromosomale Aberrationen wie Translokationen und dizentrische Chromosomen in Survivin-depletierten polyploiden Zellen. Die Inhibierung der Aurora B Kinase, einem weiteren Bestandteil des CPC, mittels eines chemischen Inhibitors zeigt analog das Auftreten von DNA Schäden, eine p53/p21waf/cip Aktivierung sowie eine Zunahme an Polyploidie, wie sie für Survivin beschrieben wurde. Diese Erkenntnisse zeigen deutlich auf, dass die DNA Schäden und der p53/p21waf/cip-abhängige G1 Arrest nach dem „knock down“ von Survivin aufgrund einer gestörten Mitose hervorgerufen wurde, während eine IAP-Funktion des Survivins unter den gewählten experimentellen Bedingungen nicht festzustellen war.

info:eu-repo/classification/ddc/570

ddc:570

Dynamika vybraných proteinů buněčné odpovědi na poškození DNA / Dynamics of selected DNA damage response proteins

Benada, Jan

January 2011

DNA damage response (DDR) represents a vital signaling network that protects genome integrity and prevents development of cancer. Therefore the study of DDR is of a crucial clinical importance and DDR proteins are promising therapeu- tic targets. Although the great advances have been made mapping out interac- tions between individual DDR proteins, better understanding of complex behav- ior of this network is still needed. One approach, which might help us in this task, is to describe the dynamics of key proteins under different conditions. The first objective of this study was to investigate whether the temporal dynamics of selected DDR proteins differ upon different genotoxic insults, particularly upon γ- irradiation and UV-C irradiation. We showed that under certain insult some DDR proteins exhibit a monotone continuous activation pulse, while the activation of others triggers a series of pulses. We observed a previously described pulsative dynamics of p53 after γ-irradiation in MCF7 cells. Interestingly, we detected a monotone increase of p53 in U2OS after γ-irradiation and similar dynamics upon UV-C irradiation. We suggest that p53 dynamics depends on the presence or ab- sence of effective negative feedback loops between the upstream p53-activating kinases and Wip1 phosphatase. In the second...