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Showing 21 to 30 of 30 (0.049 seconds)Spelling suggestions: "subject:"DNA doublestrand break"" "subject:"DNA doublestranded break""
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Funkce RAD18 v ubikvitinaci na místech dvouřetězcových DNA zlomů / Role of RAD18 in ubiquitin signaling at DNA double-strand breaksPalek, Matouš January 2021 (has links)
RAD18 is an E3 ubiquitin ligase that prevents the replication forks from collapsing caused by damaged DNA. As an important factor controlling replication, its dysregulation was shown to be associated with some human tumours. However, the clinical relevance of this finding is unknown. The aim of the thesis was evaluation of selected RAD18 variants that had been identified in breast and ovarian cancer patients. This work revealed functional defects of RAD18 variants not only in replication fork protection but also in repair of DNA double-strand breaks. This unconventional role of RAD18 is known to be dependent on upstream ubiquitination events, however, its contribution to the repair per se is not understood. This work aimed to elucidate the function of RAD18 in DNA double-strand break repair by homologous recombination focusing especially on its relationship with 53BP1. Data presented here show that RAD18 effectively disrupts 53BP1 accumulation in the repair foci by competition for the same binding partner and thus promotes resection of DNA ends. This antagonistic function of RAD18 is restricted both spatially (to the vicinity of the repair centre) and temporarily (to S phase). Moreover, it seems to be regulated by existence of RAD18 in two distinct complexes. Potential models for this regulation...
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DNA Double-Strand Break Repair : Molecular Characterization of Classical and Alternative Nonhomologous End Joining in Mitochondrial and Cell-free ExtractsKumar, Tadi Satish January 2013 (has links) (PDF)
Maintenance of genomic integrity and stability is of prime importance for the survival of an organism. Upon exposure to different damaging agents, DNA acquires various lesions such as base modifications, single-strand breaks (SSBs), and double-strand breaks (DSBs). Organisms have evolved specific repair pathways in order to efficiently correct such DNA damages. Among various types of DNA damages, DSBs are the most serious when present inside cells. Unrepaired or misrepaired DSBs account for some of the genetic instabilities that lead to secondary chromosomal rearrangements, such as deletions, inversions, and translocations and consequently to cancer predisposition. Nonhomologous DNA end joining (NHEJ) is one of the major DSB repair pathways in higher organisms.
Mitochondrial DNA (mtDNA) deletions identified in humans are flanked by short directly-repeated sequences, however, the mechanism by which these deletions arise are unknown. mtDNA deletions are associated with various types of mitochondrial disorders related to cancer, aging, diabetes, deafness, neurodegenerative disorders, sporadic and inherited diseases. Compared to nuclear DNA (nDNA), mtDNA is highly exposed to oxidative stress due to its proximity to the respiratory chain and the lack of protective histones. DSBs generated by reactive oxygen species, replication stalling or radiation represents a highly dangerous form of damage to both nDNA and mtDNA. However, the repair of DSBs in mitochondria and the proteins involved in this repair are still elusive. Animals deficient for any one of the known Classical-NHEJ factors are immunodeficient. However, DSB repair (DSBR) is not eliminated entirely in these animals suggesting evidence of alternative mechanism, ‘alternative NHEJ’ (A-NHEJ/A-EJ). Several lines of evidence also suggest that alternative and less well-defined backup NHEJ (B-NHEJ) pathways play an important role in physiological and pathological DSBR.
We studied NHEJ in different tissue mitochondrial protein extracts using oligomeric DNA substrates which mimics various endogenous DSBs. Results showed A-EJ, as the predominant pathway in mitochondria. Interestingly, immunoprecipitation (IP) studies and specific inhibitor assays suggested, mitochondrial end joining (EJ) was dependent on A-EJ proteins and independent of C-NHEJ proteins. Further, colocalization studies showed A-EJ proteins localize into mitochondria in HeLa cells. More importantly knockdown experiments showed the involvement of DNA LIGASE III in mitochondrial A-EJ. These observations highlight the central role of A-EJ in maintenance of the mammalian mitochondrial genome.
By using oligomeric DNA substrates mimicking various endogenous DSBs, NHEJ in different cancer cell lines were studied. We found that the efficiency of NHEJ varies among cancer cells; however, there was no remarkable difference in the mechanism and expression of NHEJ proteins. Interestingly, cancer cells with lower levels of BCL2 possessed efficient NHEJ and vice versa. Removal of BCL2 by immunoprecipitation and protein fractionation using size exclusion column chromatography showed elevated levels of EJ. Most importantly, the overexpression of BCL2 in vivo or the addition of purified BCL2 in vitro led to the downregulation of NHEJ in cancer cells. Further, we found that BCL2 interacts with KU proteins both in vitro and in vivo using immunoprecipitation and immunofluorescence, respectively. Hence, NHEJ in cancer cells is negatively regulated by the anti-apoptotic protein, BCL2, and this may contribute towards increased chromosomal abnormalities in cancer.
In summary, our study showed that the efficiency of EJ in cancers could be regulated by the antiapoptotic protein BCL2. However, it may not affect the mechanistic aspect of EJ. BCL2 instead may interfere with EJ by sequestering KU and preventing it from binding to DNA ends. This may help in better understanding towards increased chromosomal abnormalities in cancer. Study of mitochondrial DSBR in mammalian system highlights the central role of microhomology-mediated A-EJ in the maintenance of the mammalian mitochondrial genome and this knowledge will helpful for the development of future therapeutic strategies against variety of mitochondria associated diseases.
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Caractérisation biochimique du complexe Smc5-6Roy, Marc-André 11 1900 (has links)
Les membres de la famille SMC (Structural Maintenance of Chromosomes), présents dans tous les domaines de la vie, sont impliqués dans des processus allant de la cohésion des chromatides-sœurs jusqu’à la réparation de l’ADN. Chacun des membres de cette famille, composée de 6 membres (Smc1 à Smc6), s’associe avec un autre membre ainsi qu’à des sous-unités non-SMC pour former 3 complexes : cohésine, condensine et Smc5-6. L’implication du complexe Smc5-6 dans plusieurs aspects du maintien de l’intégrité génomique est bien démontrée. Néanmoins, une question fondamentale concernant ce complexe demeure encore sans réponse: comment peut-il être impliqué dans autant d’aspects de la vie d’une cellule? Encore à ce jour, il est difficile de répondre à cette question en raison du manque d’information disponible au sujet des activités biochimiques de ce complexe. C’est pourquoi l’objectif de ce travail consiste en la caractérisation biochimique du complexe Smc5-6.
La biochimie de cohésine et condensine suggère diverses possibilités en ce qui a trait aux activités biochimiques du complexe Smc5-6. La première étape de mon projet fut donc d’élaborer une procédure pour la purification de Smc5 et Smc6 après surexpression en levure. Après plusieurs expériences, il apparut clair que les deux protéines possèdent une activité de liaison à l’ADN simple brin (ADNsb) ainsi qu’à l’ADN double brins (ADNdb) et que, même si les protéines peuvent se lier aux deux types d’ADN, elles possèdent une plus grande affinité pour l’ADNsb. De plus, ces expériences permirent de démontrer que l’interaction entre Smc5 ou Smc6 et l’ADNsb est très stable, alors que l’interaction avec l’ADNdb ne l’est pas. Suite à l’obtention de ces résultats, la seconde étape fut la détermination de la ou des partie(s) de Smc5 et Smc6 permettant la liaison à l’ADN. Pour répondre à cette question, une dissection moléculaire fut réalisée, suivi d’une caractérisation des différents domaines constituants Smc5 et Smc6. De cette façon, il fut possible de démontrer qu’il existe deux sites de liaison à l’ADN sur Smc5 et Smc6 ; le premier site se trouvant dans le domaine «hinge» ainsi que dans la région adjacente du domaine «coiled-coil» et le second au niveau de la tête ATPase des deux protéines. Bien que les deux domaines puissent lier l’ADNsb, il fut démontré qu’une différence majeure existe au niveau de leur affinité pour ce type d’ADN. En effet, le domaine «hinge» possède une affinité plus forte pour l’ADNsb que la tête ATPase. De plus, cette dernière est incapable de lier l’ADNdb alors que le domaine «hinge» le peut. L’identification des sites de liaison à l’ADN sur Smc5 et Smc6 permettra de créer de nouveaux mutants possédant un défaut dans la liaison à l’ADN. Ainsi, l’étude du complexe Smc5-6 durant la réparation de l’ADN in vivo sera facilité. / The Smc5-6 complex is part of the SMC (Structural Maintenance of Chromosomes) family and is involved in the maintenance of genome integrity. This complex is required for the replication and repair of DNA. Unfortunately, the DNA substrates recognized by the Smc5-6 complex are still unknown. To address this gap, I used a biochemical approach to purify and functionally characterize the core of the Smc5-6 complex represented by the two SMC proteins. Subsequently, I wanted to understand which part(s) of Smc5 or Smc6 mediate their binding to DNA.
I show here that Smc5 and Smc6 bind to all types of DNA tested. Despite this ability to associate with several types of nucleic acids, they have a clear preference for single-stranded DNA (ssDNA). The ability of Smc5 and Smc6 to link DNA independently of each other suggests that both SMC proteins have the potential to target the Smc5-6 complex to its DNA substrates in vivo. Furthermore, the minimal length of ssDNA required for the binding of Smc5 or Smc6 is between 45 to 75 nucleotides. This length of ssDNA is shorter than the size of ssDNA intermediates created during DNA repair or replication reactions. In addition to having a preference for ssDNA, the binding of both SMC proteins to this type of DNA is stronger than their binding to double-stranded DNA (dsDNA). Finally, the molecular dissection of SMC proteins into functional domains revealed that there are two independent DNA-binding sites on each molecule of Smc5 or Smc6. The first region is located in the hinge domain, while the second region is located in the ATPase head of the protein. The affinity and selectivity of independent domains towards DNA substrates suggest a functional differentiation between the two DNA-binding sites of SMC molecules. Indeed, the hinge domain has a greater affinity for ssDNA than the ATPase head. In terms of selectivity, the hinge domain is capable of binding to dsDNA whereas the ATPase head cannot.
Taken together, our identification of the DNA-binding domains on Smc5 and Smc6 will enable the creation of new mutants with a defect in their DNA-binding activity. Thus, the study of the Smc5-6 complex during DNA repair, in vivo, will be facilitated.
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Les protéines suppressives de tumeurs ING1, ING2 et ING3 : régulation par sumoylation et implication dans la réponse aux dommages à l'ADN / The tumor suppressor proteins ING1, ING2 and ING3 : regulation by sumoylation and involvement in the DNA Damage ResponseGuérillon, Claire 08 October 2014 (has links)
Les gènes ING (Inhibitor of Growth) sont des gènes candidats suppresseurs de tumeurs conservés de la Levure à l'Homme. Les protéines ING ont des fonctions suppressives de tumeurs de type I ou « caretaker » car elles participent aux processus de maintien de la stabilité du génome en régulant la réplication et la réparation de l'ADN. Elles ont aussi des fonctions suppressives de tumeurs de type II ou « gatekeeper » puisqu'elles sont impliquées dans la régulation de la prolifération cellulaire de façon dépendante et indépendante de p53 et car elles contrôlent la transcription génique en participant au remodelage de la chromatine. L'objectif de ma thèse est de mieux comprendre l'implication de ING1, ING2 et ING3 dans les voies de suppression des tumeurs. Nos travaux montrent que ING1 est sumoylée sur la lysine 193 principalement par l'E3 SUMO ligase PIAS4, afin de réguler l'ancrage de ING1 sur le promoteur de gènes cibles pour réguler leur transcription. Nous avons aussi décrit pour la première fois l'implication de ING2 et de ING3 dans la réponse aux cassures double brin de l'ADN. Nous montrons que cette fonction est conservée entre ING2, ING3 et leur orthologues, respectivement, Pho23 et Yng2 chez la Levure Saccharomyces cerevisiae. ING2 contrôle l'accumulation de PIAS4 au niveau des sites de dommages et régule la sumoylation de l'E3 ubquitine ligase RNF168, afin de permettre la signalisation et la réparation des cassures double brin de l'ADN. ING3 est nécessaire à l'accumulation de 53BP1 et contrôle la réparation de ces dommages. Ces travaux contribuent donc à une meilleure connaissance du rôle des ING dans les voies de suppression des tumeurs. Ils permettent de mieux comprendre comment ING1 régule la transcription génique et décrivent une nouvelle fonction suppressive de tumeur de type I ou « caretaker » pour ING2 et ING3 dans le maintien de la stabilité du génome. / ING (Inhibitor of Growth) genes are tumor suppressor gene candidates conserved from Yeast to Humans. ING proteins have type I tumor suppressive functions or "caretaker" because they participate in the maintenance of genome stability by regulating DNA replication and repair processes. They have also tumor suppressive functions of type II or "gatekeeper" because they are involved in the regulation of cell proliferation in p53 dependent and independent manners. They also participate in the regulation of gene transcription by regulating chromatin remodeling. The aim of my thesis was to better understand how ING1, ING2 and ING3 are involved in tumor suppressive pathways. Our work shows that ING1 is sumoylated on lysine 193 mainly by the SUMO E3 ligase PIAS4 to regulate ING1 anchoring on target gene promoters to control gene transcription. We have also described the involvement of ING2 and ING3 in the DNA double strand breaks response. We show the conservation of this function between ING2, ING3 and their orthologs, respectively, Pho23 and Yng2 in Yeast Saccharomyces cerevisiae. ING2 controls the accumulation of PIAS4 at DNA damage sites and regulates the sumoylation of the E3 ubiquitin ligase RNF168, to regulate DNA double strand break signaling and repair. ING3 is necessary for the accumulation of 53BP1 and promotes DNA damage repair. This work contributes to a better understanding of the role of ING proteins in tumor suppression. It thus provides new insights of how ING1 regulates gene transcription and emphasizes a new tumor suppressive function of type I or "caretaker" for ING2 and ING3 in the genome stability maintenance.
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Implication of DNA damage and repair in viability and differentiation of muscle stem cells / Implication des dommages à l’ADN et leur réparation sur la viabilité et la différentiation des cellules souches musculairesSutcu, Haser 20 September 2018 (has links)
Les cassures double-brin (DSB) sont des dommages dangereux de l’ADN et représentent un facteur de risque pour la stabilité du génome. Le maintien de l'intégrité du génome est essentiel pour les cellules souches adultes, qui sont responsables de la régénération des tissus endommagés et de l'homéostasie tissulaire tout au long de la vie. La régénération musculaire chez l'adulte repose sur les cellules souches musculaires (cellules satellites, SCs) qui possèdent une remarquable capacité de réparation des DSB, mais dont le mécanisme sous-jacent reste inconnu. Ce projet de thèse consistait à étudier comment la différenciation musculaire est affectée lorsque la réparation des DSB est altérée, et quels sont le(s) mécanisme(s) et les conséquences de ce défaut de réparation sur la régénération musculaire. Au cours de cette étude, il est apparu de façon originale que les facteurs de réparation des DSB peuvent affecter la myogenèse, indépendamment de leur fonction dans la réparation de l'ADN. La présente étude a porté sur le rôle de la protéine kinase dépendante de l'ADN (DNA-PK), un facteur crucial pour la réparation non-homologue des DSBs (NHEJ), au cours de la différenciation musculaire chez la souris. L’étude a ciblé l'activation des SCs et la régénération musculaire in vitro et in vivo et a également abordé la régulation de cette kinase. Le rôle "canonique" de la DNA-PK, et donc du NHEJ, dans les SCs a également été étudié en présence de lésions de l'ADN radio-induites. Le rôle d’ATM, une kinase qui orchestre les réponses cellulaires aux DSB, a également été abordé dans le contexte de la régénération musculaire. Ces résultats confirment la notion émergente du rôle multifonctionnel des protéines de réparation de l’ADN dans d’autres processus physiologiques que la réparation elle-même, ce qui m’a également permis de réaliser une étude bibliographique. Ce travail i) identifie de nouveaux régulateurs de la myogenèse et ii) contribue à la compréhension de la résistance des cellules souches musculaires au stress génotoxique. Ces résultats pourraient avoir des implications dans l'amélioration des thérapies cellulaires de la dysfonction musculaire en agissant sur les régulateurs nouvellement découverts. / DNA double-strand breaks (DSBs) are dangerous DNA damages and a risk factor for genome stability. The maintenance of genome integrity is crucial for adult stem cells that are responsible for regeneration of damaged tissues and tissue homeostasis throughout life. Muscle regeneration in the adult relies on muscle stem cells (satellite cells, SCs) that have a remarkable DSB repair activity, but the underlying mechanism is not known. The aims of the present PhD project were to investigate how muscle differentiation is affected when DSB repair is impaired, and which are the mechanism(s) and the consequences on muscle regeneration. During this study, a novel possibility has arisen, namely that DSB repair factors affects myogenesis independently of their DNA repair activity, suggesting a novel function, not previously anticipated, of these factors. The present study has addressed the role of DNA-dependent protein kinase (DNA-PK), a crucial factor in non-homologous end-joining (NHEJ) repair of DSBs, in muscle differentiation in the mouse. Studies have targeted SC activation and muscle regeneration in vitro and in vivo and also addressed the regulation of this kinase. In parallel the more “canonical” role of DNA-PK, and thereby of NHEJ, has been investigated in SCs via radiation-induced DNA damage. The role of ATM, a kinase that orchestrates cellular responses to DSBs in muscle regeneration has also been addressed. These results support the emerging notion of multifunctional repair proteins in a variety of physiological processes beyond the repair process itself, on which I have conducted a bibliographical study. This work i) identifies novel regulators of myogenesis, and ii) helps understanding the resistance of muscle stem cells to genotoxic stress. It has potential implications for improving cellular therapies for muscle dysfunction by acting on the newly discovered regulators.
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Quantification of Radiation Induced DNA Damage Response in Normal Skin Exposed in Clinical SettingsSimonsson, Martin January 2011 (has links)
The structure, function and accessibility of epidermal skin provide aunique opportunity to study the DNA damage response (DDR) of a normaltissue. The in vivo response can be examined in detail, at a molecularlevel, and further associated to the structural changes, observed at atissue level. We collected an extensive skin biopsy material frompatients undergoing fractionated radiotherapy for 5 to 7 weeks. Several end-points inthe DDR pathways were examined before, during and after the treatment. Quantification of DNA double strand break (DSB) signalling focirevealed a hypersensitivity to doses below 0.3Gy. Furthermore, aconsiderable amount of foci persisted between fractions. The low dosehypersensitivity was observed throughout the treatment and was alsoobserved for several key parameters further downstream in the DDR-pathway, such as p21-associated checkpoint activation, apoptosisinduction and reduction in basal keratinocyte density (BKD).Furthermore, for dose fractions above 1.0 Gy, a distinct acceleration inDDR was observed half way into treatment. This was manifested as anaccelerated loss of basal keratinocytes, mirrored by a simultaneousincrease in DSBs and p21 expression. Quantifications of mitotic events revealed a pronounced suppression ofmitosis throughout the treatment which was clearly low dosehypersensitive. Thus, no evidence of accelerated repopulation could beobserved for fraction doses ranging from 0.05 to 2Gy. Our results suggest that the keratinocyte response primarily isdetermined by checkpoints, which leads to pre-mitotic cell elimination by permanent growth arrest and apoptosis. A comparison between the epidermal and dermal sub-compartments revealsa consistent up-regulation of the DDR response during treatment. Adifference was however observed in the recovery phase after treatment,where miR-34a and p21 remain up-regulated in dermis more persistentlythan in epidermis. Our observations suggest that the recovery phaseafter treatment can provide important clues to understand clinicalobservations such as the early and late effects observed in normaltissues during fractionated radiotherapy.
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The Role of Saccharomyces Cerevisiae MRX Complex and Sae2 in Maintenance of Genome StabilityGhodke, Indrajeet Laxman January 2015 (has links) (PDF)
In eukaryotes, the repair of DSBs is accomplished through two broadly defined processes: Non-Homologous End Joining (NHEJ) and Homologous Recombination (HR). The central step of HR is pairing and exchange of strands between two homologous DNA molecules, which is catalyzed by the conserved Rad51/RecA family of proteins. Prior to this step, an essential step in all HR pathways i.e. 5'→3' resection of broken DNA ends to generate 3' single stranded DNA tails. At the molecular level, initiation of DNA end resection is accomplished through the concerted action of MRX complex (Mre11, Rad50 and Xrs2) and Sae2 protein.
To elucidate the molecular basis underlying DSB end resection in S. cerevisiae mre11 nuclease deficient mutants, we have performed a comprehensive analysis of the role of S. cerevisiae Mre11 (henceforth called as ScMre11) in the processing of DSB ends using a variety of DNA substrates. We observed that S. cerevisiae Mre11(ScMre11) exhibits higher binding affinity for single- over double-stranded DNA and intermediates of recombination and repair and catalyzes robust unwinding of substrates possessing a3' single-stranded DNA overhang but not of 5' overhangs or blunt-ended DNA fragments. Furthermore, reconstitution of DSB end resection network in-vitro revealed that Rad50, Xrs2, and Sae2 potentiated the DNA unwinding activity of Mre11. Since the exonuclease activity of Mre11 is of the opposite polarity to that expected for resection of DSBs, unwinding activity of Mre11 in conjunction with Rad50, Xrs2, and Sae2 might provide an alternate mechanism for the generation of ssDNA intermediates for DSB end repair and HR. Additionally, ScMre11 displays strong homotypic as well as heterotypic interaction with Sae2. In summary, our results revealed important insights into the mechanism of DSB end processing and support a model in which Sae2, Rad50, and Xrs2 positively regulate the ScMre11-mediated DNA unwinding activity via their direct interactions or through allosteric effects on the DNA or cofactors.
Prompted by the closer association of MRX and Sae2 during DSB end processing, we asked whether Sae2 and its endonuclease activity is required for cellular response to replication stress caused by DNA damage. Toward this end, we examined the sensitivity of S. cerevisiae wild type, sae2Δ and various SAE2 mutant strains defective in phosphorylation and nuclease activity in the presence of different genotoxic agents, which directly or indirectly generate DSBs during replication. We found that S. cerevisiae lacking SAE2 show decreased cell viability, altered cell cycle dynamics after DNA damage, and more specifically, that Sae2 endonuclease activity is essential for these biological functions. To corroborate the genetic evidences for role of SAE2 during replicative stress, we investigated SAE2 functions in-vitro. For this, we purified native Sae2 protein and nuclease dead mutant of Sae2 i.e. sae2G270D. Our studies revealed dimeric forms of both the wild type and mutant forms of Sae2. Furthermore, Sae2 displays higher binding affinity and catalytic activity with branched DNA structures, such as Holliday junction and replication forks. By using nuclease dead Sae2 protein i.e. sae2G270D, we confirmed that the endonuclease activity is not fortuitous and is intrinsic to Sae2 polypeptide. Furthermore, nuclease-defective Mre11 stimulates Sae2endonuclease activity. Mapping of the cleavage sites of Sae2 revealed a distinct preference for cleavage on the 5' end of the Holliday junction, suggesting the importance of Sae2 nuclease during recombination mediated restart of the reversed replication fork. In summary, our data clearly demonstrate a previously uncharacterized role for Sae2 nuclease activity in resection of DSB ends, processing of intermediates of DNA replication/repair and attenuation of DNA replication stress-related defects in S. cerevisiae.
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Molecular and functional characterization of ABRAXAS and PALB2 genes in hereditary breast cancer predispositionBose, M. (Muthiah) 29 October 2019 (has links)
Abstract
Hereditary mutations in DNA damage response (DDR) genes often lead to genomic instability and ultimately tumor development. However, the molecular mechanism of how these DDR deficiencies promote genomic instability and malignancy is not well understood. Thus, the specific aim of this thesis is to identify the functional and molecular framework behind the elevated breast cancer risk observed in heterozygous PALB2 and ABRAXAS mutation carriers.
The heterozygous germline alteration in PALB2 (c.1592delT) causes a haploinsufficiency phenotype in the mutation carrier cells. Due to PALB2 haploinsufficiency, elevated Cdk activity and consequently aberrant DNA replication/damage response was observed in the PALB2 mutation carrier cells. Excessive origin firing that is indicative of replication stress was also seen in the PALB2 mutation carrier cells. In addition to replication stress, PALB2 mutation carrier cells also experience G2/M checkpoint maintenance defects. The increased malignancy risk in females associated with heterozygosity for the Finnish PALB2 founder mutation is likely to be due to aberrant DNA replication, elevated genomic instability and multiple different cell cycle checkpoint defects.
The heterozygous germline alteration in ABRAXAS (c.1082G>A) causes a dominant-negative phenotype in the mutation carrier cells. Decreased BRCA1 protein levels as well as reduced nuclear localization and foci formation of BRCA1 and CtIP was observed in the ABRAXAS mutation carrier cells. This causes disturbances in basal BRCA1-A complex localization, which is reflected by a restraint in error-prone DNA double-strand break (DSB) repair pathway usage, attenuated DNA damage response, deregulated G2/M checkpoint control and apoptosis. Most importantly, mutation carrier cells display a change in their transcriptional profile, which we attribute to the reduced nuclear levels of BRCA1. Thus, the Finnish ABRAXAS founder mutation acts in a dominant-negative manner on BRCA1 to promote genome destabilization in the heterozygous carrier cells. / Tiivistelmä
Perinnölliset muutokset DNA-vauriovasteen geeneissä johtavat usein genomin epävakauteen ja lopulta syövän kehittymiseen. Molekyylitason mekanismeja, joilla vauriovasteen vajaatoiminta ajaa genomin epävakautta ja syöpää, ei kuitenkaan ymmärretä kunnolla. Tämän väitöskirjan tavoitteena on tunnistaa solutoiminnan ja molekyylitason vaikuttajat heterotsygoottisten PALB2- ja ABRAXAS-geenimuutosten kantajien kohonneen rintasyöpäriskin taustalla.
Heterotsygoottinen ituradan suomalainen perustajamuutos PALB2-geenissä (c.1592delT) aiheuttaa haploinsuffisienssin kantajahenkilöiden soluissa. PALB2:n haploinsuffisienssin seurauksena kantajasoluissa havaittiin kohonnutta Cdk-proteiinin aktiivisuutta ja siitä johtuvaa kiihtynyttä DNA:n kahdentumista. PALB2-mutaatiota kantavissa soluissa nähtiin myös liiallista replikaation aloituskohtien käyttöä, mikä viittaa replikaatiostressiin. Replikaatiostressin lisäksi PALB2-mutaation kantajasoluilla havaittiin vaikeuksia ylläpitää solusyklin G2/M-tarkastuspisteen toimintaa. Näiden solutoiminnan poikkeavuuksien takia heterotsygoottisen PALB2 c.1592delT -mutaation kantajilla todettiin genomin epävakautta ja kohonnut syöpäriski.
Heterotsygoottinen ituradan mutaatio ABRAXAS-geenissä (c.1082G>A) aiheuttaa dominantti-negatiivisen fenotyypin mutaation kantajasoluissa. ABRAXAS-mutaatiota kantavissa soluissa havaittiin BRCA1-proteiinitasojen laskua sekä BRCA1- ja CtIP-proteiinien vähentynyttä lokalisaatiota tumaan ja DNA-vauriopaikoille. Tämä aiheuttaa häiriöitä BRCA1-A-kompleksin paikallistumisessa, mikä johtaa häiriöihin virhealttiiden DNA-kaksoisjuoste¬katkoksien korjausmekanismien käytössä, DNA-vauriovasteessa, G2/M-tarkastus-pisteen säätelyssä ja ohjelmoidussa solukuolemassa. Tärkeimpänä löydöksenä havaittiin mutaation kantajasoluissa muuttunut transkriptioprofiili, joka johtunee BRCA1-proteiinitasojen laskusta tumassa. Näin ollen suomalainen ABRAXAS-perustajamutaatio toimii dominantti-negatiivisena BRCA1:n suhteen, aiheuttaen genomin epävakautta heterotsygoottisissa kantajasoluissa.
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Kinesin-13, tubulins and their new roles in DNA damage repairPaydar, Mohammadjavad 12 1900 (has links)
Les microtubules sont de longs polymères cylindriques de la protéine α, β tubuline, utilisés dans les cellules pour construire le cytosquelette, le fuseau mitotique et les axonèmes. Ces polymères creux sont cruciaux pour de nombreuses fonctions cellulaires, y compris le transport intracellulaire et la ségrégation chromosomique pendant la division cellulaire. Au fur et à mesure que les cellules se développent, se divisent et se différencient, les microtubules passent par un processus, appelé instabilité dynamique, ce qui signifie qu’ils basculent constamment entre les états de croissance et de rétrécissement. Cette caractéristique conservée et fondamentale des microtubules est étroitement régulée par des familles de protéines associées aux microtubules. Les protéines de kinésine-13 sont une famille de facteurs régulateurs de microtubules qui dépolymérisent catalytiquement les extrémités des microtubules.
Cette thèse traite d’abord des concepts mécanistiques sur le cycle catalytique de la kinésine-13. Afin de mieux comprendre le mécanisme moléculaire par lequel les protéines de kinésine-13 induisent la dépolymérisation des microtubules, nous rapportons la structure cristalline d’un monomère de kinésine-13 catalytiquement actif (Kif2A) en complexe avec deux hétérodimères αβ-tubuline courbés dans un réseau tête-à-queue. Nous démontrons également l’importance du « cou » spécifique à la classe de kinésine-13 dans la dépolymérisation catalytique des microtubules.
Ensuite, nous avons cherché à fournir la base moléculaire de l’hydrolyse tubuline-guanosine triphosphate (GTP) et son rôle dans la dynamique des microtubules. Dans le modèle que nous présentons ici, l’hydrolyse tubuline-GTP pourrait être déclenchée par les changements conformationnels induits par les protéines kinésine-13 ou par l’agent chimique stabilisant paclitaxel. Nous fournissons également des preuves biochimiques montrant que les changements conformationnels des dimères de tubuline précèdent le renouvellement de la tubuline-GTP, ce qui indique que ce processus est déclenché mécaniquement.
Ensuite, nous avons identifié la kinésine de microtubule Kif2C comme une protéine associée à des modèles d’ADN imitant la rupture double brin (DSB) et à d’autres protéines de réparation DSB connues dans les extraits d’œufs de Xenope et les cellules de mammifères. Les cassures double brin d’ADN (DSB) sont un type majeur de lésions d’ADN ayant les effets les plus cytotoxiques. En raison de leurs graves impacts sur la survie cellulaire et la stabilité génomique, les DSB d’ADN sont liés à de nombreuses maladies humaines, y compris le cancer. Nous avons constaté que les activités PARP et ATM étaient toutes deux nécessaires pour le recrutement de Kif2C sur les sites de réparation de l’ADN. Kif2C knockout ou inhibition de son activité de dépolymérisation des microtubules a conduit à l’hypersensibilité des dommages à l’ADN et à une réduction de la réparation du DSB via la jonction terminale non homologue et la recombinaison homologue.
Dans l’ensemble, notre modèle suggère que les protéines de kinésine-13 peuvent interagir avec les dimères de tubuline aux extrémités microtubules et modifier leurs conformations, moduler l’étendue des extrêmités tubuline-GTP dans les cellules et déclencher le désassemblage des microtubules. Ces deux modèles pourraient être des clés pour démêler les mécanismes impliqués dans le nouveau rôle de Kif2C dans la réparation de l’ADN DSB sans s’associer à des polymères de microtubules. / Microtubules are long, cylindrical polymers of the proteins α, β tubulin, used in cells to construct the cytoskeleton, the mitotic spindle and axonemes. These hollow polymers are crucial for many cellular functions including intracellular transport and chromosome segregation during cell division. As cells grow, divide, and differentiate, microtubules go through a process, called dynamic instability, which means they constantly switch between growth and shrinkage states. This conserved and fundamental feature of microtubules is tightly regulated by families of microtubule-associated proteins (MAPs). Kinesin-13 proteins are a family of microtubule regulatory factors that catalytically depolymerize microtubule ends.
This thesis first discusses mechanistic insights into the catalytic cycle of kinesin-13. In order to better understand the molecular mechanism by which kinesin-13 proteins induce microtubule depolymerization, we report the crystal structure of a catalytically active kinesin-13 monomer (Kif2A) in complex with two bent αβ-tubulin heterodimers in a head-to-tail array. We also demonstrate the importance of the kinesin-13 class-specific “neck” in modulating Adenosine triphosphate (ATP) turnover and catalytic depolymerization of microtubules.
Then, we aimed to provide the molecular basis for tubulin-Guanosine triphosphate (GTP) hydrolysis and its role in microtubule dynamics. Although it has been known for decades that tubulin-GTP turnover is linked to microtubule dynamics, its precise role in the process and how it is driven are now well understood. In the model we are presenting here, tubulin-GTP hydrolysis could be triggered via the conformational changes induced by kinesin-13 proteins or by the stabilizing chemical agent paclitaxel. We also provide biochemical evidence showing that conformational changes of tubulin dimers precedes the tubulin-GTP turnover, which indicates that this process is triggered mechanically.
Next, we identified microtubule kinesin Kif2C as a protein associated with double strand break (DSB)-mimicking DNA templates and other known DSB repair proteins in Xenopus egg extracts and mammalian cells. DNA double strand breaks (DSBs) are a major type of DNA lesions with the most cytotoxic effects. Due to their sever impacts on cell survival and genomic stability, DNA DSBs are related to many human diseases including cancer. Here we found that PARP and ATM activities were both required for the recruitment of Kif2C to DNA repair sites. Kif2C knockdown/knockout or inhibition of its microtubule depolymerizing activity led to accumulation of endogenous DNA damage, DNA damage hypersensitivity, and reduced DSB repair via both non-homologous end-joining (NHEJ) and homologous recombination (HR). Interestingly, genetic depletion of KIF2C, or inhibition of its microtubule depolymerase activity, reduced the mobility of DSBs, impaired the formation of DNA damage foci, and decreased the occurrence of foci fusion and resolution.
Altogether, our findings shed light on the mechanisms involved in kinesin-13 catalyzed microtubule depolymerization. Our tubulin-GTP hydrolysis model suggests that kinesin-13 proteins may interact with tubulin dimers at microtubules ends and alter their conformations, modulate the extent of the GTP caps in cells and trigger microtubule disassembly. These two models could be keys to unravel the mechanisms involved in the novel role of Kif2C in DNA DSB repair without associating with microtubule polymers.
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Cascades of genetic instability resulting from compromised break-induced replicationVasan, Soumini January 2013 (has links)
Indiana University-Purdue University Indianapolis (IUPUI) / Break-induced replication (BIR) is a mechanism to repair double-strand breaks
(DSBs) that possess only a single end that can find homology in the genome. This situation can result from the collapse of replication forks or telomere erosion. BIR frequently produces various genetic instabilities including mutations, loss of heterozygosity, deletions, duplications, and template switching that can result in copy-number variations (CNVs). An important type of genomic rearrangement specifically linked to BIR is half crossovers (HCs), which result from fusions between parts of recombining chromosomes. Because HC formation produces a fused molecule as well as a broken chromosome fragment, these events could be highly destabilizing. Here I demonstrate that HC formation results from the interruption of BIR caused by a defective replisome or premature onset of mitosis. Additionally, I document the existence of half crossover instability cascades (HCC) that resemble cycles of non-reciprocal translocations (NRTs) previously described in human tumors. I postulate that HCs represent a potent source of genetic destabilization with significant consequences that mimic those observed in human diseases, including cancer.
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