Global ETD Search

171	Non-Natural Nucleotides as Modulators of ATPases Eng, Kevin T. 06 July 2010 (has links) No description available. Biochemistry Pharmacology ATPases Nucleo(t)side analogs MDR DNA replication
172	Study of the Mechanistic Features of DNA Replication Restart in Neisseria Gonorrhoeae Sunchu, Bharath 21 August 2012 (has links) No description available. Biochemistry Neisseria gonorrhoeae DNA replication restart PriA PriB CGS-15493
173	Structure and Function of B. subtilis MutL Lorenowicz, Jessica 09 1900 (has links) Maintaining genomic integrity is important for any organism. DNA mismatch repair (MMR) serves to correct errors that occur during DNA replication and recombination, such as unpaired bases or mismatched bases. Mutl is a key player and serves to coordinate protein-protein interactions. Recently it has been shown that human Mutl functions as an endonuclease and that this activity is imperative for functioning MMR. In this work, the X-ray crystal structure of the C-terminal endonuclease domain of Bacillus subtilis Mutl (BsMutL-CTD) is presented. Diffraction quality crystals of BsMutL-CTD were grown using vapor diffusion. The crystal structure of BsMutL-CTD was solved using multiwavelength anomalous diffraction. The structure reveals a putative metal binding site which clusters closely in space with endonuclease motif. Using the structure and sequence homology, several mutations were made and an investigation into the endonuclease activity of BsMutL was performed. BsMutL was confirmed to be a manganese-dependent endonuclease and key residues which contribute to endonuclease function were identified. / Thesis / Master of Science (MSc) genomic integrity DNA mismatch repair DNA replication protein-protein interactions
174	Characterization of cell cycle regulatory proteins in Plasmodium falciparum Patterson, Shelley Ann 01 July 2003 (has links) No description available. DNA replication; Plasmodium falciparum Life Sciences Microbiology Molecular Biology
175	NMR investigations of strand slippage in CTG repeat expansion and primer-template misalignment in low fidelity DNA replication. / CUHK electronic theses & dissertations collection January 2007 (has links) CTG repeat is one of the most common triplet repeat sequences that have been found to form slipped-strand structures leading to self-expansion during DNA replication. The lengthening of these repeats causes the onset of neurodegenerative diseases such as myotonic dystrophy. Through designing a series of CTG repeat sequences with high hairpin populations, systematic analysis of imino and methyl proton spectra study has been carried out to investigate the length and structural roles of CTG repeats in affecting the propensity of hairpin formation. Direct NMR evidence has been obtained to support three types of hairpin structures in sequences containing one to ten CTG repeats. The differences in loop structures and extent of interactions observed in the hairpins account for the differences in hairpin formation propensity and explain how slippage occurs that lead to triplet repeat expansion. / DNA has been found to adopt unusual structures leading to different types of mutations, which can ultimately cause genetic diseases and cancers. In this thesis, investigations on (i) structural role of CTG repeats in trinucleotide repeat expansion, (ii) primer-template structures in strand slippage during low fidelity replication and (iii) sequence effect of nucleotide downstream of thymine templates on primer-template structures have been carried out using NMR spectroscopy. / In addition, NMR structural investigations have also been carried out to determine solution structures of primer-template models. NMR evidence confirms misalignment can occur in primer-templates upon misincorporation of dNTP opposite a template sequence, leading to bulge formation in the primer-template. Depending on the template sequence, further incorporation of dNTP can bring about either realignment or further stabilization of the primer-template structure. Consequently, either mismatch or deletion errors will occur, leading to base substitution or frameshift mutation. These results imply that DNA sequences do not only play a passive role to store genetic information in the replication process, they also play an active structural role in governing the types of mutation during low-fidelity DNA replication. / Some of the results in this thesis have been reported in the following peer-reviewed journals: (1) Chi, L. M. and Lam, S. L. (2005) Structural roles of CTG repeats in slippage expansion during DNA replication. Nucleic Acids Res, 33, 1604-1617. (2) Chi, L. M. and Lam, S. L. (2006) NMR investigation of DNA primer-template models: structural insights into dislocation mutagenesis in DNA replication. FEBS Lett. , 580, 6496-6500. (3) Chi, L. M. and Lam, S. L. (2007) NMR investigation of primer-template models: structural effect of sequence downstream of a thymine template on mutagenesis in DNA replication. Biochemistry, 46, 9292-9300. / Chi, Lai Man. / "August 2007." / Adviser: Lam Sik Lok. / Source: Dissertation Abstracts International, Volume: 69-02, Section: B, page: 0877. / Thesis (Ph.D.)--Chinese University of Hong Kong, 2007. / Includes bibliographical references (p. 102-112). / Electronic reproduction. Hong Kong : Chinese University of Hong Kong, [2012] System requirements: Adobe Acrobat Reader. Available via World Wide Web. / Electronic reproduction. [Ann Arbor, MI] : ProQuest Information and Learning, [200-] System requirements: Adobe Acrobat Reader. Available via World Wide Web. / Abstract in English and Chinese. / School code: 1307. DNA replication Nuclear magnetic resonance spectroscopy Nucleotide sequence Trinucleotide repeats Base Sequence DNA Replication DNA Magnetic Resonance Spectroscopy Trinucleotide Repeats
176	Structural and functional characterisation of Mcb1 and the MCMᴹᶜᵇ¹ complex in Schizosaccharomyces pombe Schnick, Jasmin January 2014 (has links) The MCM helicase plays an important role in eukaryotic DNA replication, unwinding double stranded DNA ahead of the replication fork. MCM is a hetero-hexamer consisting of the six related proteins, Mcm2-Mcm7. The distantly related MCM-binding protein (MCM-BP) was first identified in a screen for proteins interacting with MCM2-7 in human cells and was found to specifically interact with Mcm3-7 but not Mcm2. It is conserved in most eukaryotes and seems to play an important role in DNA replication but its exact function is not clear yet. This study contributes to the understanding of the fission yeast homologue of MCM-BP, named Mcb1, but also of MCM-BP in general. Results presented in this thesis document the initial biochemical characterisation of the complex Mcb1 forms with Mcm proteins, the MCMᴹᶜᵇ¹ complex. Interactions of Mcb1 with Mcm proteins, potential interaction sites between the proteins and the size of the complex were analysed using a variety of methods, including tandem affinity purification, co-immunoprecipitation, sucrose gradients and in vitro pull-down assays. Sequence analysis and structure prediction were utilised to gain some insight into Mcb1 and MCM-BP ancestry and structure. Results presented here indicate that fission yeast Mcb1 shares homology with Mcm proteins and forms a complex with Mcm3-Mcm7 but not Mcm2 and thus replaces the latter in an alternative high molecular weight complex that is likely to have an MCM-like appearance. Deletion of mcb1⁺ showed that Mcb1 is essential in fission yeast. To examine the cellular function of the protein, temperature-sensitive mutants were generated. Inactivation of Mcb1 leads to an increase in DNA damage and cell cycle arrest in G2-phase depending on the activation of the Chk1 dependent DNA damage checkpoint. Similar observations were made when Mcb1 was overexpressed, indicating that certain levels of the protein are important for accurate DNA replication. Construction of truncated versions of Mcb1 suggested that almost the full-length protein is needed for proper function. 572.8
177	Identification de nouveaux mécanismes de régulation temporelle des origines de réplication dans les cellules humaines / Identification of new mechanisms of temporal regulation of DNA replication origins in human cells Guitton-Sert, Laure 11 December 2015 (has links) La duplication de l'ADN au cours de la phase S est initiée à partir de l'activation de plusieurs dizaines de milliers d'origines de réplication. La mise en place des origines a lieu au cours de la phase G1 sous la forme de complexe de pré-réplication (pré-RC) et leur activation est orchestrée par un programme spatio-temporel. La régulation spatiale détermine les origines qui seront activées et la régulation temporelle, ou timing de réplication, détermine le moment de leur activation. En effet, toutes ces origines ne sont pas activées en même temps durant la phase S : certaines origines seront activées en début de phase S, d'autre en milieu, ou d'autre à la fin. Ce programme est établi en tout début de phase G1, au " point de décision du timing ". C'est un programme très robuste qui signe l'identité d'une cellule, son état de différenciation et le type cellulaire à laquelle elle appartient. Il a aussi été montré qu'il est altéré dans des situations pathologiques, en particulier le cancer, sans qu'on ne comprenne très bien les raisons mécanistiques. De manière générale, les mécanismes moléculaires qui régulent le timing de réplication sont méconnus. Le premier volet de ma thèse a permis l'identification d'un nouveau régulateur du timing de réplication : il s'agit de l'ADN polymérase spécialisée Thêta. Recrutée à la chromatine très tôt en phase G1, elle interagit avec des composants du pré-RC, et régule le recrutement des hélicases réplicatives à la chromatine. Enfin, sa déplétion ou sa surexpression entraîne une modification du timing de réplication à l'échelle du génome. Dans la deuxième partie de ma thèse, j'ai exploré les mécanismes qui régulent ce programme temporel d'activation des origines suite à un stress réplicatif. J'ai identifié un mécanisme de régulation transgénérationnel inédit : la modification du timing de réplication de domaines chromosomiques ayant subi un stress réplicatif au cycle cellulaire précédent. Des cellules-filles issues d'une cellule ayant subi des problèmes de réplication dans des domaines fragiles (riches en AT, et donc potentiellement structurés, et pauvres en origines) présentent un timing plus précoce de l'activation des origines au niveau de ces domaines. Ce nouveau processus biologique d'adaptation est particulièrement intéressant dans un contexte tumoral de haut stress réplicatif chronique car ce pourrait être un moyen pour la cellule tumorale de survivre à son propre stress réplicatif mais aussi aux thérapies antitumorales qui sont nombreuses à cibler la réplication de l'ADN. / DNA duplication in S phase starts from thousands of initiation sites called DNA replication origins. These replication origins are set in G1 as pre-replication complexes (pre-RC) and fired in S phase following a spatio-temporal program of activation. This program determines which origins will be fired and when. Indeed, all the origins are not fired in the same time and we can distinguish early, middle and late replication origins. This temporal regulation is called "replication timing" and is determined at the "timing decision point" (TDP) in early G1. It's a robust program, which participates to the definition of cell identity, in term of differentiation state or cell type. However, the precise molecular mechanisms involved are poorly understood. Defective timing program has been evidenced in pathological contexts, in particular in cancers, but the mechanisms of this deregulation remain unclear. In the first part of my PhD, I contributed to the discovery of a new regulator of the origin timing program: the specialized DNA polymerase Theta (Pol Theta). Pol Theta is loaded onto chromatin in early G1, coimmunoprecipitates with pre-RC components and modulates the recruitment of Mcm helicases at TDP. Moreover, depletion or overexpression of Pol Theta modifies the timing of replication at a fraction of chromosomal domains. The second part of my work aimed at exploring the mechanisms that regulates replication timing after a replicative stress. I identified a totally new transgenerational adaptive mechanism of DNA replication timing regulation: the modification of the timing of origin activation at chromosomal domains that have suffered from a replicative stress during the previous cell cycle. Daughter cells from a cell that has experienced replication stress at particular domains (late replicating domains, AT rich so they can form structured DNA, and poor in origin density) shows advanced origin activation within these regions. This new biological process in response to replicative stress could be of particular interest in the context of cancer since, tumor cells are characterized by high level of intrinsic chronic replicative stress. This new mechanism may favor cancer cell survival despite replication stress, particularly upon treatments with anti-tumor agents that target DNA. Réplication de l'ADN Timing de réplication Origines de réplication ADN polymérase Thêta Stress réplicatif DNA replication Replication timing DNA replication origins DNA polymerase Theta Replicative stress
178	Hypoxia-induced chromatin changes and ATM signalling Olcina del Molino, Mónica January 2014 (has links) The DNA damage response (DDR) is a complex signalling cascade triggered in response to stress, in an attempt to maintain genomic integrity. Components of this pathway, such as ATM-mediated signalling, have been proposed to act as a barrier in the early stages of tumourigenesis. Regions of low oxygen concentrations (hypoxia) occur in most solid tumours and are associated with a poor prognostic outcome. Here, we investigated the DDR induced following hypoxia-induced replication stress in an attempt to decipher the mechanism of ATM activation in response to physiological stresses that do not induce DNA damage. We hypothesized that hypoxia-mediated chromatin changes could impact on ATM signalling. We have characterised H3 methylation in response to hypoxia and found oxygen dependent changes in H3K9me3, including both global and replication fork associated increases in this histone modification. Importantly, we have found that decreases in H3K9me3 result in loss or attenuation of ATM activation. Notably, in a background of replication stress and increased H3K9me3, ATM inhibition or loss leads to accumulation of DNA damage and a significant decrease in replication rates in hypoxia. We propose that when replication stress occurs in the presence of hypoxia-induced chromatin changes, ATM activation is facilitated by the induction of H3K9me3. In this context, we propose a novel and stress specific role for ATM-mediated signalling in maintaining replication and preventing the generation of DNA breaks that may compromise genomic integrity. Moreover, the biological consequences of the hypoxia-induced chromatin context and in particular hypoxia-induced H3K9me3 include the repression of APAK, a negative regulator of p53. Activation of p53 is a key consequence of the hypoxia-induced DDR. Here we found that SETDB1, one of the H3 methyltransferases induced by hypoxia, mediates APAK repression. We propose that H3K9me3 plays a role in regulating APAK expression to allow optimal induction of p53 dependent apoptosis in hypoxic conditions suggesting a further role for H3K9me3 in facilitating DDR signalling in hypoxia. Together, these data suggest that the hypoxic chromatin context is critical for the role of the DDR as a barrier to tumourigenesis and predict that altering the chromatin landscape in combination with DNA damaging therapies would be efficacious in the treatment of hypoxic tumours. 572.8
179	DNA Replication and Trinucleotide Repeat Instability in Myotonic Dystrophy Type 1 Cleary, John 06 August 2010 (has links) The expansion of gene-specific trinucleotide repeats is responsible for a growing list of human disorders, including myotonic dystrophy type 1 (DM1). Repeat instability for most of these disorders, including DM1, is characterized by complex patterns of inherited and ongoing tissue-specific instability and pathogenesis. While the mechanistic basis behind the unique locus-specific instability of trinucleotide repeats is currently unknown, DNA metabolic processes are likely to play a role. My thesis involves investigating the contribution of DNA replication to the trinucleotide instability of myotonic dystrophy type 1. Herein I have designed an in vivo primate model system, based on the SV40 replication system, to assess the contribution of DNA replication to DM1 repeat instability. This system allows the assessment, under controlled conditions, and manipulation of variables that may affect replication-associated repeat instability, under a primate cellular system. Using the SV40 model system, I not only confirmed previous observations that repeat length and replication direction affect repeat instability, but also for the first time determined that the location of the replication origin relative to the repeat tract plays an important role in repeat instability. This novel observation allowed for the development of a fork-shift model of repeat instability, in which cis-elements adjacent to the repeat tract affect replication, in turn altering the propensity for repeat instability. To further my study of DNA replication in DM1 repeat instability, I have mapped the origin of replication adjacent to the DM1 locus in human patient cells and the tissues of DM1 transgenic mice actively undergoing repeat instability. The position of the replication origins adjacent to the repeat tract at the DM1 locus places several known cis-elements, including CTCF binding sites, in a position to alter replication as predicted by the fork-shift model. My analysis of the CTCF sites showed them capable of altering replication and repeat instability at the DM1 locus. Taken together these results suggest that the placement of replication origins, repeat tracts and cis-elements, may mark trinucleotide repeat tracts, such as the DM1, for locus-, tissue- and development-specific replication-associated repeat instability. DNA replication neurodegeneration triplet repeat cis-element instability model system 0369 0307
180	The cell cycle and DNA damage-dependent regulation of Cdt1 in schizosaccharomyces pombe Shepherd, Marianne E. A. January 2012 (has links) Cdt1 is a conserved and essential eukaryotic protein that is required for the licensing step of DNA replication. In order to control replication licensing and ensure a single round of DNA replication occurs per cell cycle, Cdt1 is subject to strict regulation. In Metazoa and S. pombe, Cdt1 is targeted for ubiquitylation and proteolysis in S phase and after DNA damage by the CRL4Cdt2 ubiquitin ligase. CRL4Cdt2 is activated in Metazoa by an unusual mechanism that requires an interaction between the substrate and chromatin-loaded proliferating cell nuclear antigen (PCNA). This study addressed the involvement of PCNA in S. pombe Cdt1 proteolysis. A mutational analysis was undertaken to establish whether the Cdt1-PCNA interaction is conserved in S. pombe and the extent to which it regulates CRL4Cdt2-dependent turnover of the protein. S. pombe Cdt1 was shown to interact with PCNA in vivo and two variant PCNA-interacting peptide (PIP) motifs were identified in the protein. The two motifs function near-redundantly to promote both the Cdt1-PCNA interaction and the CRL4Cdt2-dependent proteolysis of Cdt1 in S phase and after DNA damage. The mutational analysis also resulted in the characterisation of two in-frame AUG codons in the cdt1+ reading frame. The second in-frame AUG codon was shown to be the principal initiator codon and was required to maintain wildtype Cdt1 protein levels and cell viability. CRL4Cdt2 is emerging as an important regulator of proteins that are involved in the control of cell cycle progression and the maintenance of genome stability. However, there are a number of outstanding questions regarding the mechanism and regulation of CRL4Cdt2. In order to address these questions, a genomics approach was taken to identify novel genes involved in Cdt1 regulation. A screen of non-essential S. pombe genes identified 17 candidate genes that, when inactivated, caused up-regulation of Cdt1. Unexpectedly, deletion of genes involved in homologous recombination resulted in a Rad3-dependent up-regulation of Cdt1. Further work is required to establish the biological significance of this finding. 572.8645

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