Global ETD Search

21	RELATIONSHIPS BETWEEN TELOMERIC SEQUENCES AND STRUCTURES, DNA REPLICATION, AND THE FUNCTION OF THE WERNER SYNDROME PROTEIN Edwards, Deanna 01 January 2012 (has links) All human chromosomes end with protective structures called telomeres, which consist of thousands of double-stranded TTAGGG repeats and end in a 3’ guanine-rich overhang. These structures shorten normally during each round of replication, and extremely short telomeres along with telomere dysfunction are thought to contribute to the development of aging and cancer. Although many proteins have roles in telomere maintenance, WRN, which is a 3’ to 5’ helicase that is deficient in the premature aging disorder Werner’s syndrome, has been proposed to play multiple roles at telomeres. In this study, I focus on the effect of telomeric sequences and/or structures formed during DNA replication or recombination and how WRN functions at these sites. This study suggests that WRN may promote proper replication of telomeres by accurately aligning telomeric sequences during replication fork regression, potentially the first step in responding to a blockage, such as DNA damage. However, even in the presence of WRN, replication of telomeric sequences is difficult, possibly due to the ability of G-rich sequences to form secondary structures such as G-quadruplexes. I demonstrate that the translesion polymerase pol η, as well as a variety of other polymerases, is unable to synthesize past an intramolecular G-quadruplex formed from telomeric sequence on the template strand. Furthermore, in physiological salt concentrations, WRN favors binding and unwinding a structure that mimics a strand invasion intermediate over other similar structures especially when it possesses G-telomeric sequence. In addition, WRN promotes unwinding of these structures in a direction that would promote additional annealing and strand invasion, supporting a role for WRN in promoting telomeric recombination and formation of a T-loop, a proposed protective structure specific to telomeres. Overall, the data suggest that telomeres may pose problems in replication due to the G-rich, repeating nature of the structures, while WRN may aid in promoting proper replication at these and other replication blocks. Furthermore, WRN may play a role in promoting additional formation of T-loops and other telomeric recombination, thus supporting the relationship of WRN, telomere maintenance, and potentially development of certain aging characteristics. Werner Protein Telomeres Replication Homologous Recombination T-loops Medical Molecular Biology
22	Analysis of nucleotide synthesis and homologous recombination repair in Schizosaccharomyces pombe Blaikley, Elizabeth Jane January 2014 (has links) Nucleotide synthesis is a conserved and highly regulated response to DNA damage, required for the efficient repair of DNA double strand breaks (DSB) by homologous recombination (HR). This is essential to prevent loss of heterozygosity (LOH) and maintain genome stability. The aim of this study was to identify new genes important for HR through roles in damage-induced nucleotide synthesis. A screen was performed to identify S. pombe gene deletion strains whose DSB sensitivity was suppressed by deleting the ribonucleotide reductase (RNR) inhibitor spd1<sup>+</sup> to promote nucleotide synthesis. The screen identified a number of genes including ddb1<sup>+</sup>, cdt2<sup>+</sup>, rad3<sup>+</sup> and csn1<sup>+</sup> which have known roles in nucleotide synthesis. Distinct roles were identified for the DNA damage checkpoint in suppressing LOH. rad3<sup>+</sup>, rad26<sup>+</sup>, rad17<sup>+</sup> and the rad9<sup>+</sup>, rad1<sup>+</sup> and hus1<sup>+</sup> genes encoding the 9-1-1 complex were required for DNA damage-induced nucleotide synthesis through Cdt2 induction to promote Spd1 degradation. The HR repair defect of rad3<sup>+</sup> and rad26<sup>+</sup> deletion strains was partially suppressed by spd1<sup>+</sup> deletion. However, the HR repair defect of rad17<sup>+</sup>, rad9<sup>+</sup>, rad1<sup>+</sup> and hus1<sup>+</sup> deletion strains was not suppressed. An additional role was confirmed for Rad17 and the 9-1-1 complex in preventing LOH by promoting DSB resection. A role was identified for the Gcn5 histone acetyl transferase (HAT) protein module, consisting of Gcn5, Ngg1, Ada2 and Sgf29, in suppressing DSB sensitivity by promoting nucleotide synthesis. This was independent of Cdt2 or RNR protein levels. The Gcn5 HAT module was also found to regulate DSB repair pathway choice consistent with previous observations. Deletion of gcn5<sup>+</sup>, ngg1<sup>+</sup> or ada2<sup>+</sup> decreased HR and increased non-homologous end joining. Surprisingly, deletion of spd1<sup>+</sup> in a gcn5∆, ngg1∆ or ada2∆ background also promoted HR. This predicts a role for nucleotide pools in regulating DSB repair pathway choice. Eleven other candidates showed repeatable suppression of DSB sensitivity following spd1<sup>+</sup> deletion. However many of these candidates did not show reduced nucleotide levels. This suggests deleting spd1<sup>+</sup> may also suppress DSB sensitivity by a different mechanism. 572.8
23	Charakterizace antirekombinázové aktivity lidské FBH1 helikázy / Characterization of Antirecombinase Activity of Human FBH1 Helicase Šimandlová, Jitka January 2012 (has links) Homologous recombination (HR) is an essential mechanism for accurate repair of DNA double-strand breaks (DSBs). However, HR must be tightly controlled because excessive or unwanted HR events can lead to genome instability, which is a prerequisite for premature aging and cancer development. A critical step of HR is the loading of RAD51 molecules onto single-stranded DNA regions generated in the vicinity of the DSB, leading to the formation of a nucleoprotein filament. Several DNA helicases have been involved in the regulation of the HR process. One of these is human FBH1 (F-box DNA helicase 1) that is a member of SF1 superfamily of helicases. As a unique DNA helicase, FBH1 additionally possesses a conserved F-box motif that allows it to assemble into an SCF complex, an E3 ubiquitin ligase that targets proteins for degradation. FBH1 has been implicated in the restriction of nucleoprotein filament stability. However, the exact mechanism of how FBH1 controls the RAD51 action is still not certain. In this work, we revealed that FBH1 actively disassembles RAD51 nucleoprotein filament. We also show that FBH1 interacts with RAD51 and RPA physically in vitro. Based on these data, we propose a potential mechanism of FBH1 antirecombinase function.
24	Genetic Analysis of Mitotic Recombination in Saccharomyces cerevisiae O'Connell, Karen Eileen January 2016 (has links) <p>Mitotic genome instability can occur during the repair of double-strand breaks (DSBs) in DNA, which arise from endogenous and exogenous sources. Studying the mechanisms of DNA repair in the budding yeast, Saccharomyces cerevisiae has shown that Homologous Recombination (HR) is a vital repair mechanism for DSBs. HR can result in a crossover event, in which the broken molecule reciprocally exchanges information with a homologous repair template. The current model of double-strand break repair (DSBR) also allows for a tract of information to non-reciprocally transfer from the template molecule to the broken molecule. These “gene conversion” events can vary in size and can occur in conjunction with a crossover event or in isolation. The frequency and size of gene conversions in isolation and gene conversions associated with crossing over has been a source of debate due to the variation in systems used to detect gene conversions and the context in which the gene conversions are measured. </p><p>In Chapter 2, I use an unbiased system that measures the frequency and size of gene conversion events, as well as the association of gene conversion events with crossing over between homologs in diploid yeast. We show mitotic gene conversions occur at a rate of 1.3x10-6 per cell division, are either large (median 54.0kb) or small (median 6.4kb), and are associated with crossing over 43% of the time. </p><p>DSBs can arise from endogenous cellular processes such as replication and transcription. Two important RNA/DNA hybrids are involved in replication and transcription: R-loops, which form when an RNA transcript base pairs with the DNA template and displaces the non-template DNA strand, and ribonucleotides embedded into DNA (rNMPs), which arise when replicative polymerase errors insert ribonucleotide instead of deoxyribonucleotide triphosphates. RNaseH1 (encoded by RNH1) and RNaseH2 (whose catalytic subunit is encoded by RNH201) both recognize and degrade the RNA in within R-loops while RNaseH2 alone recognizes, nicks, and initiates removal of rNMPs embedded into DNA. Due to their redundant abilities to act on RNA:DNA hybrids, aberrant removal of rNMPs from DNA has been thought to lead to genome instability in an rnh201Δ background. </p><p> In Chapter 3, I characterize (1) non-selective genome-wide homologous recombination events and (2) crossing over on chromosome IV in mutants defective in RNaseH1, RNaseH2, or RNaseH1 and RNaseH2. Using a mutant DNA polymerase that incorporates 4-fold fewer rNMPs than wild type, I demonstrate that the primary recombinogenic lesion in the RNaseH2-defective genome is not rNMPs, but rather R-loops. This work suggests different in-vivo roles for RNaseH1 and RNaseH2 in resolving R-loops in yeast and is consistent with R-loops, not rNMPs, being the the likely source of pathology in Aicardi-Goutières Syndrome patients defective in RNaseH2.</p> / Dissertation Genetics Molecular biology Cellular biology crossing over gene conversion genomics homologous recombination RNase H biology
25	Réponses post-réplicatives au stress réplicatif chronique faible ou endogène, chez les mammifères / Post-S phase responses to chronic low or endogenous replicative stress, in mammalian cells Magdalou, Indiana 09 December 2014 (has links) La réplication de l’ADN est un phénomène physiologique essentiel à la transmission du patrimoine génétique mais est aussi une source importante de stress endogène. Le stress réplicatif peut conduire à une instabilité génomique et a été mis en évidence à une étape très précoce du développement tumoral et de la sénescence. La recombinaison homologue (RH) est un processus de réparation qui permet la prise en prise en charge du stress réplicatif. De ce fait, un défaut de RH devrait permettre de révéler les stress réplicatifs endogènes. Ainsi, une progression ralentie des fourches de réplication a été observée dans des cellules déficientes pour la RH (RH-), et ce en absence de tout traitement exogène (Daboussi 2008). De plus, de nombreux travaux ont mis en évidence la présence de défauts mitotiques dans les cellules RH-, en absence de tout traitement exogène (Griffin 2000; Kraakman-van der Zwet 2002; Bertrand 2003; Daboussi 2005; Laulier 2011; Rodrigue 2013). L’origine de ces défauts mitotiques spontanés reste peu claire. En effet, la RH étant un processus préférentiellement actif au cours des phases S et G2, le lien avec la mitose reste à éclaircir. Cette thèse a pour but de comprendre l’impact du stress réplicatif très faible ou endogène sur les phases post-réplicatives du cycle cellulaire. Dans un premier temps, je me suis intéressée à l’impact de ce stress sur la mitose. Les résultats obtenus montrent que le traitement des cellules contrôle à de très faibles doses d’hydroxyurée (HU) n’affecte pas la progression dans le cycle cellulaire mais induit cependant une diminution de la vitesse de réplication, comparable à celle observée dans les cellules RH-. De plus le traitement des cellules contrôle à des faibles doses d’HU induit l’apparition de défauts mitotiques, notamment des centrosomes surnuméraires, à la même fréquence que dans les cellules RH- non traitées. Inversement, l’ajout de précurseurs de nucléotides dans les cellules RH- permet de supprimer la diminution de la vitesse de réplication ainsi que les centrosomes mitotiques surnuméraires. Ainsi, un stress réplicatif subtil, qui n’impacte pas de façon détectable la progression dans les phases S et G2 du cycle cellulaire, ni l’entrée en mitose, cause cependant des défauts mitotiques sévères. De façon importante, les centrosomes mitotiques surnuméraires peuvent entrainer des mitoses multipolaires, impactant ainsi l’ensemble du génome. Ces données mettent en évidence la connexion qui existe entre la réplication des chromosomes et leur ségrégation. Dans un second temps, j’ai étudié l’impact du stress réplicatif faible ou endogène en phase G2. Cette étude a été réalisée en utilisant des cellules RH-, ainsi qu’un modèle d’induction de faible stress réplicatif après traitement à très faible dose d’HU. La présence de foyers pRPA-Ser33 en phase G2 a été observée dans ces deux modèles, mettant en évidence des zones de stress réplicatif. Après traitement à très faible dose d’HU, nous observons également la présence en phase G2 de foyers 53BP1 et RAD51 qui colocalisent partiellement avec les foyers pRPA-Ser33. L’analyse en spectrométrie de masse après co-immunoprécipitation de la protéine 53BP1 en phase G2 a permis d’établir un lien avec des protéines impliquées dans le contrôle de l’assemblage du fuseau mitotique ainsi que dans le points de contrôle mitotique, étayant ainsi le lien entre le stress réplicatif et les défauts mitotiques. Pour finir, l’immunoprécipitation de la chromatine liée à la protéine pRPA-Ser33 en phase G2, suivie d’un séquençage (ChIPseq), a permis de révéler l’absence d’enrichissement au niveau des sites fragiles communs et de mettre en évidence un enrichissement au niveau des régions promotrices de certains gènes, notamment de gènes impliqués dans la régulation du cycle cellulaire et de la mort cellulaire. Ces résultats soulignent le lien entre le stress réplicatif très faible ou endogène et l’instabilité chromosomique, qui peut mener à l’initiation tumorale. / DNA replication is a physiological process, essential for genetic information transmission but DNA replication is also an important source of endogenous stress. Replicative stress can lead to genomic instability and has been reported in early-stage malignancies and senescence. Homologous recombination is a repair process which can handle replicative stress. Therefore, a defect in homologous recombination could reveal endogenous replicative stresses. Consistently, a slow down in replication fork progression has been observed in homologous recombination deficient (HR-) cells, in absence of any exogenous treatment (Daboussi et al. 2008). In addition, several studies have shown the presence of mitotic defects in HR- cells, in absence of any exogenous treatment (Griffin 2000; Kraakman-van der Zwet 2002; Bertrand 2003; Daboussi 2005; Laulier et al. 2011; Rodrigue 2013). The origin of these spontaneous mitotic defects is still unclear. Indeed, homologous recombination is preferentially active in S and G2 phases thus, the link with mitosis remains to be elucidated. The aim of this thesis is to understand the impact of a low or endogenous replicative stress on post-replicative phases. First, I studied the impact of a low or endogenous replicative stress on mitosis. Control cells were treated with very low hydroxyurea doses, that did not affected cell cycle progression but did slow down the replication fork progression to the same level than unchallenged HR- cells. Importanntly, exposure of the control cells to these low hydroxyurea doses generated the same mitotic defects, notably extra centrosomes, and to the same extent than in untreated HR- cells. Reciprocally, supplying nucleotide precursors to HR- cells suppressed both their replication deceleration and mitotic extra centrosome phenotypes. Therefore, subtle replication stress that does not impact S and G2 phase progression nor the entry in mitosis, nevertheless causes severe mitotic defects. Importantly, mitotic extra centrosome can lead to multipolar mitosis and then impact the whole genome stability. These data highlight the crosstalk between chromosome replication and segregation. Secondly, I studied the impact of low or endogenous replicative stress on G2 phase. This study was done using HR- cells as well as control cells treated with very low HU doses to induce a very low replicative stress. In both of these models, the presence of pRPA-Ser33 foci was observed in G2 phase, highlighting replicative stress regions. After very low HU treatement, we observed 53BP1 and RAD51 foci in G2 phase. These foci partially colocalized with pRPA-Ser33 foci in G2 phase. Mass spectrometry analyse after 53BP1 coimmunoprecipitation allowed to etablish a link between proteins involved in mitotic spindle assembly control and in mitotic checkpoint. These data support the link between replicative stress and mitotic defects. Lastly, the immmunoprecipitation of the chromatin interacting with pRPA-Ser33 in G2 phase, followed by sequencing (ChIPseq) allowed to reveal the absence of common fragile site enrichment and to highlight an enrichment at promoter regions of genes involved in cell cycle and cell death regulation. These data underline the link between very low or endogenous replicative stress and chromosomal instability, which can lead to tumorigenesis. Cancer Instabilité génomique Stress réplicatif Recombinaison homologue Cancer Genomic instability Replicative stress Homologous recombination
26	Metabolismo de serina: caracterização de serina hidroximetiltransferase de Trypanosoma cruzi. / Metabolism of serine: characterization of serine hydroxymethyltransferase of Trypanosoma cruzi. Baptista, Carlos Gustavo 29 March 2017 (has links) A doença de Chagas é uma doença causada pelo protozoário parasita Trypanosoma cruzi, que afeta cerca de 10 milhões de pessoas, principalmente nas Américas. O T. cruzi utiliza aminoácidos como importante fonte de energia e em vários processos biológicos como diferenciação, resistência a condições de estresse e invasão de células hospedeiras. A serina está envolvida em muitas vias biosintéticas. Uma das funções relevantes da serina é a formação de compostos C1 para a biossíntese de nucleotídeos. O uso de serina para esse fim é iniciado pela Serina Hidroximetiltransferase, cuja atividade foi detectada em T. cruzi, mas seu papel na biologia do parasita permanece pouco explorado. Neste trabalho, identificamos um gene que codifica uma Serina Hidroximetiltransferase putativa com dupla localização (citoplasmática e mitocondrial). Por recombinação homóloga, obtemos parasitas knockouts heterozigotos nos quais um alelo de SHMT foi substituído pelo gene da neomicina fosfotransferase. Os parasitas knockouts não mostraram diferenças na taxa de crescimento das formas epimastigotas ou na metaciclogênese in vitro. Porém, os parasitas knockouts mostraram uma diminuição significativa tanto no índice de infecção como no número de tripomastigotas liberados de células CHO-K1 infectadas com formas metacíclicas knockout. / Chagas disease is a disorder caused by the protozoa parasite Trypanosoma cruzi, which affects about 10 million people, mainly in the Americas. T. cruzi uses amino acids as an important energy source and in several biological processes such as differentiation, resistance to stress conditions and in the host-cell invasion. Serine is involved in many biosynthetic pathways. One of the relevant functions of serine is the formation of C1 compounds for the biosynthesis of nucleotides. The use of serine for that purpose is initiated by Serine Hydroxymethyltransferase, whose activity was detected in T. cruzi but its role in the biology of parasite remains poorly explored. In this work we identified a putative gene encoding a SHMT with dual localization, cytoplasmic and mitochondrial. We generated a single knockout cell line by homologous recombination in which one allele of SHMT was replaced by the neomycin phosphotransferase gene. Knockout parasites showed no difference in epimastigote growth rate or in in vitro metacyclogenesis. However, knockout parasites showed a significant decrease in both, infection index and in the number of trypomastigotes released from CHO-K1cells infected with knockout metacyclic forms. Knockout Homologous recombination Índice de infecção Infection index Knockout Recombinação homóloga SHMT SHMT
27	Uso do silenciamento gênico mediado por RNA de interferência e de TAL effector nucleases para aumento de eventos gene targeting em células de cão / Use of RNAi-mediated gene silencing and TAL effector nucleases to enhance gene targeting events in dog cells Pinho, Raquel de Mello e 25 August 2014 (has links) A inserção de DNA exógeno no genoma hospedeiro é conseguida principalmente através da utilização de vias de reparo como a junção de pontas não homólogas, que possui caráter aleatório, e a recombinação homóloga, que possibilita o gene targeting. Algumas ferramentas como as TAL Effector Nucleases (TALENs) e o RNA interferência (RNAi) podem ser utilizadas para aumentar a taxa de integração específica e assim melhorar a eficiência e o direcionamento da edição gênica. Nesse trabalho utilizamos o silenciamento gênico mediano por short interference RNA (siRNA) para inibição temporária dos genes ATF7IP uma metiltrasferase, EP300 uma acetiltransferase e KU70 (NHEJ) e um par de TALENs complementares a uma região do gene da distrofina canina. Células Caninas MDCK I foram transfectadas por lipofectamina 2000 (Invitrogen) com 320pmol de siRNAs para ATF7IP e Ep300; e 64 pmol do SiRNA para KU70 em diferentes grupos, 40 horas depois as células foram transfectadas com 15 μg vetor molde derivado do pEGFP-N1 (Clonatech) e com 10 μg dos RNAm das TALENs. A seleção se deu em meio DMEM high com 600μg/ mL de G418 (Lonza) por 14-16 dias. As colônias coletadas através de biópsias foram analisadas por Polimerase Chain Reaction e sequenciamento gênico. Três pares de primers foram utilizados; um controle endógeno (GAPDH), um controle interno do inserto (Neo qPCR) e um para confirmação da recombinação homóloga (DMD3). Os grupos apresentaram grande variação na taxa de mortalidade celular e consequentemente no número de colônias: Com o grupo ATF7IP+Vetor (648c) apresentando maior número de colônias e o grupo EP300+Ku70+Vetor+TALENs o menor (1c). A maior taxa de recombinação ocorreu nos grupos no grupo ATF7IP +Ku70+Vetor+TALENs com 40% das células positivas para neomicina apresentado o evento gene targeting, um aumento considerável na taxa de recombinação quando comparada a porcentagem de 3,1% do controle transfectado somente com o vetor molde. Mostrando que o uso conjunto das TALENs com siRNAs foi um sucesso para o aumento de eventos de edição gênica direcionada. / The insertion of exogenous DNA into a host genome is achieved primarily through the use of DNA repair pathways such as Non-Homologous End Joining (NHEJ) and the Homologous Recombination (HR). The integration by NHEJ has a random feature and is much more common than HR insertions, which are more likely to produce gene targeting events . TAL effector nucleases (TALENs) and RNA interference (RNAi) can be used to increase the rate of specific integration and thus improving the efficiency of gene editing. In this work, we used short interference RNA (siRNA)-mediated gene silencing for transient inhibition of genes ATF7IP (implicated in histone methylation), EP300 (acetyltransferase) and Ku70 (essential to NHEJ) and a pair of TALENs RNAm complementary to canine muscle dystrophin (DMD) gene. MDCK I Canine Cells were transfected by lipofectamine 2000 (Invitrogen) with 320 pmol of siRNAs for ATF7IP and EP300; and 64 pmol of siRNA for Ku70 in different groups. After 40 hours cells were transfected with 15 μg of a vector derived from pEGFP- N1 (Clontech) containing two regions homologous to the canine DMD gene (left arm length: 873 bp and right arm length: 1370 bp) and 10 μg of TALEN mRNA. The cell selection was achieved with DMEM high glucose with 600μg/ml G418 for 14-16 days. The colonies collected through biopsies were analyzed by polymerase chain reaction and gene sequencing. Three pairs of primers were used; an endogenous control (GAPDH) , an internal control of the insert (Neo qPCR) and a primer set to confirm the occurrence of homologous recombination events (DMD3). .Groups showed great variation in cell death rate and consequently in the number of colonies: ATF7IP+Vector had highest number of colonies (648c) and the group EP300+Ku70+Vetor+TALENs the lowest one (1c) The highest rate of homologous recombination was in ATF7IP +Ku70+Vetor+TALENs group that had 40% of the neomycin positives cells confirmed as gene targeting events, a considerable increase in the recombination rate compared to the 3.1% in the control group transfected only with the template vector. That shows that the combined use of siRNAs and TALENs was a success for increasing directed gene editing events. Gene targeting Gene targeting Homologous recombination Recombinação homóloga RNAi RNAi TALENs TALENs
28	Investigating the recombinational response to replication fork barriers in fission yeast Jalan, Manisha January 2016 (has links) Timely completion of DNA replication in each cell cycle is crucial for maintaining genomic integrity. This is often challenged by the presence of various replication fork barriers (RFBs). On collision with a RFB, the fate of the replication fork remains uncertain. In some cases, the integrity of the fork is maintained until the barrier is removed or the fork is rescued by merging with the incoming fork. However, fork stalling can cause dissociation of all of the associated replication proteins (fork collapse). If this occurs, the cell's recombination machinery can intervene to help restart replication in a process called recombination-dependent replication (RDR). Programmed protein-DNA barriers like the Replication Terminator Sequence-1 (RTS1) have been used to demonstrate that replication fork blockage can induce recombination. However, it remains unclear how efficiently this recombination gives rise to replication restart and whether the restarted replication fork exhibits the same fidelity as an origin-derived fork. It is also unknown whether accidental replication barriers induce recombination in the same manner as programmed barriers. In this study, I introduce recombination reporters at various sites downstream of RTS1 to obtain information on both the fidelity and efficiency of replication restart. I find that unlike break induced replication (BIR), the restarted fork gives rise to hyper-recombination at least 75 kb downstream of the barrier. Surprisingly, fork convergence, rather than inducing recombination, acts to prevent or curtail genetic instability associated with RDR. I also investigate a number of genetic factors that have a role in either preventing or promoting genome instability associated with the progression of the restarted fork. To compare RTS1 with an accidental protein-DNA barrier, a novel site-specific barrier system (called MarBl) was established based on the human mariner transposase, Hsmar1, binding to its transposon end. Replication fork blockage at MarBl strongly induces recombination, more so than at RTS1. This appears to be a general feature of accidental barriers as introduction of the E. coli TusB-TerB site-specific barrier in S. pombe gives rise to a similar effect. Here, I compare and contrast accidental barriers with programmed barriers. I observe that there is very little replication restart, if any, at MarBl measured by direct repeat recombination downstream. This points to the fact that accidental barriers do not trigger fork collapse in the same way as programmed RFBs and that the increased recombination that they cause may be a consequence of the inability of replication forks to terminate correctly, owing to the bi-directional nature of the barrier. Several genetic factors are assessed for their impact on MarBl-induced recombination, which further highlights both similarities and differences with RTS1-induced recombination. 572
29	DNA synthesis during double-strand break repair in Escherichia coli Azeroglu, Benura January 2015 (has links) Efficient and accurate repair of DNA double strand breaks (DSBs) is required to maintain genomic stability in both eukaryotes and prokaryotes. In Escherichia coli, DSBs are repaired by homologous recombination (HR). During this process, DNA synthesis needs to be primed and templated from an intact homologous sequence to restore any information that may have been lost on the broken DNA molecule. Two critical late stages of the pathway are repair DNA synthesis and the processing of Holliday junctions (HJs). However, our knowledge of the detailed mechanisms of these steps is still limited. Our laboratory has developed a system that permits the induction of a site-specific DSB in the bacterial chromosome. This break forms in a replication dependent manner on one of the sister chromosomes, leaving the second sister chromosome intact for repair by HR. Unlike previously available systems, the repairable nature of these breaks has made it possible to physically investigate the different stages of DNA double-strand break repair (DSBR) in a chromosomal context. In this thesis, I have addressed some fundamental questions relating to repair DNA synthesis and processing of HJs by using a combination of mutants defective in specific biochemical reactions and an assay that I have developed to detect repair DNA synthesis, using a polar termination sequence (terB). First, by using terB sites located at different locations around the break point, it was shown that the DnaB-dependent repair forks are established in a coordinated manner, meaning that the collision of the repair forks occurs between two repair DNA synthesis initiation sites. Second, DSBR was shown to require the PriB protein known to transduce the DNA synthesis initiation signal from PriA protein to DnaT. Conversely, the PriC protein (known as an alternative to PriB in some reactions) was not required in this process. PriB was also shown to be required to establish DnaB-dependent repair synthesis using the terB assay. Third, the establishment and termination of repair DNA synthesis by collision of converging repair forks were shown to occur independently of HJ resolution. This conclusion results from the comparison of the viability of single and double mutants, deficient in either the establishment of DNA synthesis, HJ resolution or in both reactions, subjected to DSBs and from the study of the DNA intermediates that accumulated in these mutants as detected by two-dimensional gel electrophoresis. Fourth, the role of RecG protein during DSB repair was investigated. Solexa sequencing analyses showed that recG null mutant cells undergoing DSBs accumulate more DNA around the break point (Mawer and Leach, unpublished data). This phenomenon was further investigated by two different approaches. Using terB sites in different locations around the break point and ChIP-Seq analyses to investigate the distribution of RecA in a recG null mutant demonstrating that the establishment of repair forks depends on the presence of RecG. Further studies using PriA helicase-dead mutant showed that the interplay between RecG and PriA proteins is essential for the establishment of correctly oriented repair forks during DSBR. As a whole, this work provides evidence on the coordinated nature of the establishment and termination of DNA synthesis during DSBR and how this requires a correct interplay between PriA-PriB and RecG. A new adapted model of homologous recombination is presented. 572.8
30	Promoting Genome Stability via Multiple DNA Repair Pathways Cukras, Scott 26 February 2015 (has links) Maintaining genome integrity is indispensible for cells to prevent and limit accruement of deleterious mutations and to promote viable cell growth and proliferation. Cells possess a myriad of mechanisms to detect, prevent and repair incurred cellular damage. Here we discuss various proteins and their accompanying cellular pathways that promote genome stability. We first investigate the NEDD8 protein and its role in promoting homologous recombination repair via multiple Cullin E3 ubiquitin ligases. We provide specific mechanisms through which, UBE2M, an E2 conjugating enzyme, neddylates various Cullin ligases to render them catalytically active to degrade their substrates by the proteasome. We show that CUL1, CUL2 and CUL4 are important in regulating various steps in the DNA damage response. Our data indicates that UBE2M and the neddylation pathway are important for genome stability. Our second topic discusses the role of the USP1- UAF1 deubiquitinating enzyme in promoting homologous recombination. We show that USP1-UAF1 interact with and stabilize RAD51AP1 (RAD51- Associated Protein 1). RAD51AP1 has previously been reported to promote homologous recombination by facilitating recombinase activity of RAD51, an essential protein involved in homologous recombination repair. We show that USP1, UAF1 and RAD51AP1 depletion leads to genome instability. Our data demonstrates the importance of these proteins in promoting genome integrity via homologous recombination. Cullin Homologous Recombination NEDD8 RAD51AP1 UBE2M USP1-UAF1 Cell Biology Microbiology Molecular Biology

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