Global ETD Search

301	Rôle des chaperons d’histones dans la réplication et la réparation de l’ADN / Role of histone chaperones in the replication and repair of DNA Liu, Danni 23 February 2018 (has links) La chromatine chez les eucaryotes, porte des informations génétiques et épigénétiques. Les mécanismes garantissant le maintien de ces informations lors de la division cellulaire ou la réparation de l’ADN sont encore mal connus et ils constituent l’enjeu principal du projet de thèse. Plus particulièrement, l’objectif du projet de thèse est de chercher à comprendre comment les chaperons d’histones coordonnent leur action avec des partenaires associés à la fourche de réplication pour conserver les marques épigénétiques portées par les histones parentales et les reporter sur les histones nouvellement synthétisées. Cette thèse décrit précisément comment ASF1 (Anti Silencing Function 1) coopère avec le complexe CAF-1 (Chromatin Assembly Factor 1) et la sous-unité de l’hélicase réplicative MCM2 (Mini Chromosome Maintenance 2), pour la prise en charge des H3-H4 dans la réplication et la réparation de l’ADN.La thèse s’intéresse également à la régulation de l’activité de ces chaperons d’histones par des kinases activées suite à des stress réplicatifs ou des dommages de l’ADN. En particulier nous avons cherché à mieux comprendre comment l’ajout de groupements phosphate sur ASF1 par une enzyme appelée TLK (Tousled Like Kinase) module son activité au cours du cycle cellulaire et en réponse aux dommages de l’ADN. La caractérisation de l'importance des sites phosphorylés sur les propriétés de liaison du chaperon, permet de mieux comprendre le rôle joué par différent forme d’ASF1 dans l’assemblage des histones sur l’ADN et le maintien des informations épigénétiques. Le travail de thèse contient d’analyses biochimiques et structurales par une combinaison de techniques (SEC-MALS, AUC, ITC, RMN, cristallographie des rayons X) et d’analyses fonctionnelles sur des modèles cellulaires. / In eukaryotes, chromatin carries both, the genetic and epigenetic information. Mechanisms implicated in maintenance of these information during cell division or DNA repair remain poorly understood and they constitute the main issue of this thesis project. More specifically, the goal of the project is to understand how histone chaperones coordinate their action with partners associated with the replication fork to recognize and preserve the epigenetic marks carried by parental histones and to copy on the newly synthesized histones. The work unravels how ASF1 (Anti-Silencing Function 1) cooperates with the CAF-1 complex (Chromatin Assembly Factor 1) and with the replicative helicase subunit MCM2 (Mini Chromosome Maintenance 2), for the management of H3-H4 histones in DNA replication and repair.Moreover, this thesis investigates the regulation of histone chaperones activities by kinases activated after a replicative stress or DNA damage. In particular, we analyzed the consequences of ASF1 phosphorylation by the enzyme called TLK (Tousled like kinase). The activity of TLK is modulated during the cell cycle and after DNA damage. Characterization of the importance of phosphorylated sites on the chaperone binding properties, allows a better understanding of the role played by different forms of ASF1 in the assembly of histones on DNA and maintenance of epigenetic information. The thesis work included biochemical and structural analysis with a combination of different techniques (SEC-MALS, AUC, ITC, NMR, X-ray crystallography) and functional analysis in cellular models. Chaperon d'histone RMN et Cristallographie Kinase phosphorylation Réplication et Réparation de l'ADN Histone chaperone NMR and Crystallography Kinase phosphorylation DNA Replication and Repair
302	Replication Stress Induced by the Ribonucleotide Reductase Inhibitors Guanazole, Triapine, and Gemcitabine in Fission Yeast Alyahya, Mashael Yahya A 04 May 2022 (has links) No description available. Pharmacology Toxicology Replication stress ribonucleotide reductase hydroxyurea guanazole triapine gemcitabine fission yeast S. pombe DNA replication checkpoint
303	Structural Mechanisms of the Sliding Clamp and Sliding Clamp Loader: Insights into Disease and Function: A Dissertation Duffy, Caroline M. 15 July 2016 (has links) Chromosomal replication is an essential process in all life. This dissertation highlights regulatory roles for two critical protein complexes at the heart of the replication fork: 1) the sliding clamp, the major polymerase processivity factor, and 2) the sliding clamp loader, a spiral-shaped AAA+ ATPase, which loads the clamp onto DNA. The clamp is a promiscuous binding protein that interacts with at least 100 binding partners to orchestrate many processes on DNA, but spatiotemporal regulation of these binding interactions is unknown. Remarkably, a recent disease-causing mutant of the sliding clamp showed specific defects in DNA repair pathways. We aimed to use this mutant as a tool to understand the binding specificity of clamp interactions, and investigate the disease further. We solved three structures of the mutant, and biochemically showed perturbation of partnerbinding for some, but not all, ligands. Using a fission yeast model, we showed that mutant cells are sensitive to select DNA damaging agents. These data revealed significant flexibility within the binding site, which likely regulates partner binding. Before the clamp can act on DNA, the sliding clamp loader places the clamp onto DNA at primer/template (p/t) junctions. The clamp loader reaction couples p/t binding and subsequent ATP hydrolysis to clamp closure. Here we show that composition (RNA vs. DNA) of the primer strand affects clamp loader binding, and that the order of ATP hydrolysis around the spiral is likely sequential. These studies highlight additional details into the clamp loader mechanism, which further elucidate general mechanisms of AAA+ machinery. DNA Replication DNA-Binding Proteins DNA Primers Dissertations, UMMS Amino Acids, Peptides, and Proteins Biochemistry Molecular Biology Structural Biology
304	Interaction between telomeres and the nuclear envelope in human cells : dynamics and molecular mechanism / Interaction entre les télomères et la membrane nucléaire dans les cellules humaines : dynamique et mécanisme moléculaire Kychygina, Ganna 25 September 2019 (has links) Le matériel génétique contenant l'information des cellules humaines se présente sous forme de chromosomes linéaires dont l'extrémité est protégée par une structure appelée télomères. Les télomères correspondent à une séquence d'ADN répétée, recouverte de protéines spécifiques, qui permettent aux cellules d'étiqueter l'extrémité de leurs chromosomes afin de les différencier des cassures internes de l'ADN nécessitant une réparation. Ainsi, ils jouent un rôle prépondérant dans la protection du génome. Les chromosomes sont organisés et compartimentés dans le noyau de la cellule. Cette organisation est primordiale, la proximité des chromosomes à la membrane nucléaire qui délimite ce noyau est essentielle pour de nombreuses fonctions régulatrices du génome, comme l'activation et la répression des gènes contenant les informations. A chaque division cellulaire, cette organisation est perdue après le désassemblage de la membrane nucléaire et la condensation de la chromatine qui va permettre de correctement répartir les chromosomes entre les cellules filles. Après la division, les noyaux des cellules filles se reforment, la membrane nucléaire est rétablie, et les chromosomes sont repositionnés comme dans la cellule mère. Ce mécanisme de mémoire spatiale est encore inconnu mais est vital au maintien de la stabilité du génome. Une large proportion de télomères sont ancrés à la membrane nucléaire en fin de division, et y restent durant la reformation du noyau. Le laboratoire s'intéresse à cette association afin de caractériser son rôle pendant cette phase clé du cycle cellulaire. Nous cherchons à comprendre ce fonctionnement chez les cellules normales et les cellules de patients atteints de pathologies associées au vieillissement accéléré. Ce projet de thèse à pour but de comprendre l'impact d'une déformation de la membrane nucléaire sur le matériel génétique, et sur l'intégrité des télomères qui protègent l'information génétique. Nous utilisons des techniques de pointe de microscopie, et de biologie cellulaire et moléculaire afin de mieux comprendre le lien entre l'organisation du noyau et le maintien de la stabilité du génome. / The material that contains genetic information of human cells consists in linear chromosomes. The extremities of chromosomes are protected by a specific structure called telomeres. Telomeres are made of repeated DNA sequence, covered by special proteins that prevent cells to recognize extremities of their chromosomes as internal DNA break, thus not to perform unnecessary repair that will result in genome instability. Therefore, telomeres play a major role in genome protection. Chromosomes are spatially organized in the cell nucleus. This organization is important as positioning of chromosomes in the nucleus ensures proper regulatory functions of the genome, such as activation or repression of genes. During the cell division process, this organization is lost after nuclear membrane disassembly and the condensation of DNA, to allow correct segregation of chromosomes between daughter cells. After cell division, the nuclei of daughter cells are reformed, and nuclear membrane is reconstructed. The chromosomes are then relocated as in the mother cell. This mechanism of spatial memory is not well understood yet, but is key to maintain stability of the genome. A large proportion of telomeres are anchored to the nuclear membrane at the end of mitosis, and stay during nuclear envelope reformation. Our laboratory focuses on characterizing the role of telomere anchoring during this important phase of cell cycle. In particular, we want to understand this mechanism in normal cells and cells from patients with premature aging disease. This thesis aims to understand the impact of nuclear envelope abnormalities on the genetic material, in particular on telomere integrity, as telomeres protect genetic information. Here, we use microscopy approaches and techniques of molecular and cellular biology to better understand the link between nuclear organisation and genome stability maintenance. Télomères Enveloppe nucléaire Dommages de l`ADN Vieillissement Sénescence Réplication de l’ADN Telomeres Nuclear envelope DNA damage Aging Senescence DNA replication
305	Analysis of Human Y-Family DNA Polymerases and PrimPol by Pre-Steady-State Kinetic Methods Tokarsky, E. John Paul January 2018 (has links) No description available. Biochemistry Biology Biophysics DNA polymerase PrimPol Pre-steady-state kinetics translesion dna synthesis Y-family DNA polymerase DNA replication biochemistry
306	Identification of novel small molecule inhibitors of proteins required for genomic maintenance and stability Shuck, Sarah C. 29 July 2010 (has links) Indiana University-Purdue University Indianapolis (IUPUI) / Targeting uncontrolled cell proliferation and resistance to DNA damaging chemotherapeutics using small molecule inhibitors of proteins involved in these pathways has significant potential in cancer treatment. Several proteins involved in genomic maintenance and stability have been implicated both in the development of cancer and the response to chemotherapeutic treatment. Replication Protein A, RPA, the eukaryotic single-strand DNA binding protein, is essential for genomic maintenance and stability via roles in both DNA replication and repair. Xeroderma Pigmentosum Group A, XPA, is required for nucleotide excision repair, the main pathway cells employ to repair bulky DNA adducts. Both of these proteins have been implicated in tumor progression and chemotherapeutic response. We have identified a novel small molecule that inhibits the in vitro and cellular ssDNA binding activity of RPA, prevents cell cycle progression, induces cytotoxicity and increases the efficacy of chemotherapeutic DNA damaging agents. These results provide new insight into the mechanism of RPA-ssDNA interactions in chromosome maintenance and stability. We have also identified small molecules that prevent the XPA-DNA interaction, which are being investigated for cellular and tumor activity. These results demonstrate the first molecularly targeted eukaryotic DNA binding inhibitors and reveal the utility of targeting a protein-DNA interaction as a therapeutic strategy for cancer treatment. cisplatin RPA cancer DNA repair Cisplatin DNA repair -- Regulation DNA replication -- Regulation Cancer cells -- Proliferation Cancer -- Chemotherapy
307	Genomic instability at a polypurine/polypyrimidine repeat sequence Zavada, Nathen S. 02 September 2022 (has links) No description available. Biochemistry Biology Biomedical Research Cellular Biology Genetics Molecular Biology DNA replication genomic instability break-induced replication DNA translocation COPS2
308	Evidence for Endoreduplication: Germ Cell DNA Levels Prior to Chromatin Diminution in Mesocyclops Edax Rasch, Ellen M., Wyngaard, G. A. 01 June 2001 (has links) We studied the functional significance of marked differences in the DNA content of somatic cells and germ line nuclei by static Feulgen-DNA cytophotometry for several species of microcrustaceans that exhibit chromatin diminution during very early stages of embryogenesis. Mature females and males showed many gonadal nuclei with elevated amounts of DNA that persist until dispersal of this "extra" DNA throughout the cytoplasm as fragments and coalescing droplets of chromatin during anaphase of the diminution division. animals chromatin crustacea (cytology genetics) DNA (isolation & purification) DNA replication female germ cells male Biological Sciences
309	UVSSA regulates transcription-coupled genome maintenance Liebau, Rowyn Church January 2024 (has links) DNA damage is a constant threat to our genomes which drives genome instability and contributes to cancer progression. DNA damage interferes with important DNA transactions such as transcription and replication. DNA lesions are removed by repair pathways that ensure genome stability during transcription and replication. Here, we identify and characterize distinct roles for the ultra violet stimulated scaffold protein A (UVSSA) in the maintenance of genome stability during transcription in human cells. First, we unravel a novel function for UVSSA in transcription-coupled repair of DNA interstrand crosslinks (ICLs), genotoxic adducts that covalently bind opposing strands of the DNA and block transcription and replication. UVSSA knockout cells are sensitive to ICL inducing drugs, and UVSSA is specifically required for transcription-coupled repair of ICLs in a fluorescence-based reporter assay. Based on analysis of the UVSSA protein interactome in crosslinker treated cells we propose a model for transcription-coupled ICL repair (TC-ICR) that is initiated by stalling of transcribing RNA polymerase II (Pol II) at an ICL. Stalled Pol II is first bound by CSA and CSB, followed by UVSSA which recruits TFIIH to initiate downstream lesion removal steps. Second, we establish that UVSSA counteracts MYC dependent transcription stress to promote genome stability in cells aberrantly expressing the cMYC oncogene. UVSSA knockdown sensitizes cells to MYC expression, resulting in synthetic sickness and increased doubling time. UVSSA knockdown impacts Pol II dynamics in MYC activated cells. We conclude that UVSSA is required for regulation of Pol II during MYC induced transcription to prevent transcription stress. Together, these studies expand our understanding of UVSSA’s role in genome stability during transcription and elucidates the poorly understood transcription-coupled ICL repair pathway. Molecular biology DNA damage DNA repair DNA replication Scaffold proteins Genomes Genetic transcription--Regulation Cancer--Genetic aspects
310	Interactions Between the Organellar Pol1A, Pol1B, and Twinkle DNA Replication Proteins and Their Role in Plant Organelle DNA Replication Morley, Stewart Anthony 01 March 2019 (has links) Plants maintain organelle genomes that are descended from ancient microbes. Ages ago, these ancient microbes were engulfed by larger cells, beginning a process of co-evolution we now call the endo-symbiotic theory. Over time, DNA from the engulfed microbe was transferred to the genome of the larger engulfing cell, eventually losing the ability to be free-living, and establishing a permanent residency in the larger cell. Similarly, the larger cell came to rely so much on the microbe it had engulfed, that it too lost its ability to survive without it. Thus, mitochondria and plastids were born. Nearly all multicellular eukaryotes possess mitochondria; however, different evolutionary pressures have created drastically different genomes in plants versus animals. For one, animals have very compact, efficient mitochondrial genomes, with about 97% of the DNA coding for genes. These genomes are very consistent in size across different animal species. Plants, on the other hand, have mitochondrial genomes 10 to more than 100 times as large as animal mitochondrial genomes. Plants also use a variety of mechanisms to replicate and maintain their DNA. Central to these mechanisms are nuclear-encoded, organelle targeted replication proteins. To date, there are two DNA polymerases that have been identified in plant mitochondria and chloroplasts, Pol1A and Pol1B. There is also a DNA helicase-primase that localizes to mitochondria and chloroplasts called Twinkle, which has similarities to the gp4 protein from T7 phage. In this dissertation, we discuss the roles of the polymerases and the effects of mutating the Pol1A and Pol1B genes respectively. We show that organelle genome copy number decreases slightly and over time but with little effect on plant development. We also detail the interactions between Twinkle and Pol1A or Pol1B. Plants possess the same organellar proteins found in animal mitochondria, which are homologs to T7 phage DNA replication proteins. We show that similar to animals and some phage, plants utilize the same proteins in similar interactions to form the basis of a DNA replisome. However, we also show that plants mutated for Twinkle protein show no discernable growth defects, suggesting there are alternative replication mechanisms available to plant mitochondria that are not accessible in animals. Arabidopsis DNA replication plant organelles DNA polymerase DNA helicase-primase qPCR yeast-two-hybrid Life Sciences Molecular Biology

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