Global ETD Search

11	Characterization of the role of Orc6 in the cell cycle of the budding yeast <em>Saccharomyces cerevisiae</em> Semple, Jeffrey January 2006 (has links) The heterohexameric origin recognition complex (ORC) acts as a scaffold for the G1 phase assembly of pre-replicative complexes. Only the Orc1-5 subunits are required for origin binding in budding yeast, yet Orc6 is an essential protein for cell proliferation. In comparison to other eukaryotic Orc6 proteins, budding yeast Orc6 appears to be quite divergent. Two-hybrid analysis revealed that Orc6 only weakly interacts with other ORC subunits. In this assay Orc6 showed a strong ability to self-associate, although the significance of this dimerization or multimerization remains unclear. Imaging of Orc6-eYFP revealed a punctate sub-nuclear localization pattern throughout the cell cycle, representing the first visualization of replication foci in live budding yeast cells. Orc6 was not detected at the site of division between mother and daughter cells, in contrast to observations from metazoans. An essential role for Orc6 in DNA replication was identified by depleting the protein before and during G1 phase. Surprisingly, Orc6 was required for entry into S phase after pre-replicative complex formation, in contrast to what has been observed for other ORC subunits. When Orc6 was depleted in late G1, Mcm2 and Mcm10 were displaced from chromatin, the efficiency of replication origin firing was severely compromised, and cells failed to progress through S phase. Depletion of Orc6 late in the cell cycle indicated that it was not required for mitosis or cytokinesis. However, Orc6 was shown to be associated with proteins involved in regulating these processes, suggesting that it may act as a signal to mark the completion of DNA replication and allow mitosis to commence. Biology Cell Cycle Budding yeast DNA replication ORC pre-RC
12	Identifying novel factors involved into heterochromatin formation in budding yeast / Identification de nouveaux facteurs impliqués dans la formation d'hétérochromatine chez la levure Saccharomyces cerevisiae Nikolov, Ivaylo 26 September 2014 (has links) Chez la levure à bourgeon, l’établissement de domaines silencieux pour la transcription nécessite le recrutement du complexe SIR (Silencing Information Regulator).Mon travail de thèse s’est attaché à étudier une nouvelle voie d’établissement de la répression transcriptionnelle par les SIRs. Des travaux récents ont montré que la répétition en tandem de protéines fortement liées à l’ADN favorise la mise en silence d’un gène rapporteur voisin (Dubarry et al. 2011).En combinant des approches génétiques et moléculaires, j’ai pu montrer qu’un locus composé de 120 répétitions du site opérateur de l'opéron lactose (lacO) liées par la protéine LacI génère un stress chromatinien local et représente une source d'instabilité génomique. Cette instabilité étant limitée par la recombinaison homologue.Dans la seconde partie de ma thèse, j'ai étudié la dynamique d’établissement de la répression par les complexes lacO/LacI et montré que la répression transcriptionnelle et le recrutement du complexe SIR s'établissent sur plusieurs cycles cellulaires. En outre, mes résultats montrent que le complexe SIR stabilise les nucléosomes au niveau des complexes ADN / protéines de forte affinité.Enfin, deux cribles génétiques m’ont permis d’identifier les complexes HIR et LSM comme des facteurs impliqués dans l’hétérochromatinisation induite par les répétitions lacO/LacI. Les connaissances actuelles de ces complexes étant restreintes à la régulation de la transcription et au post-traitement des ARN messagers, d'autres études seront nécessaires pour disséquer le lien entre ces complexes et l'inhibition transcriptionnelle déclenchée par les complexes lacO /lacI. / Silent domains in budding yeast are formed by the recruitment and spreading of the Silent Information Regulator (SIR) complex.Previous studies showed that an array of tight protein-DNA complexes has the ability to trigger SIR dependent silencing of an ectopically placed EADE2I reporter (Dubarry et al. 2011). It was proposed that replication stress arising due to difficulties to replicate the array of tight protein-DNA complexes is the source of this phenomenon. In my work I have demonstrated that an array of 120 lacO repeats tightly bound by a LacI protein is a source of genomic instability. Investigating the genetic requirements for this event, I have demonstrated that homologous recombination pathways maintain the stability of the locus. My work is consistent with previous reports in fission yeast demonstrating that lacO/LacI is a chromatin stress site (Sofueva et al. 2011). As a second part of my PhD project, using an inducible system that I have developed, I followed the dynamics of establishment of silencing of an ectopically placed reporter gene. My results demonstrate that transcriptional silencing in this system takes many cell cycles to be established. Additionally, I have identified a novel role of the SIR proteins in stabilizing nucleosomes. In an attempt to elucidate the functional link between lacO/LacI and EADE2I silencing, I have performed two SGA (synthetic genetic array) screens. I have identified the HIR and LSM complexes involved into transcriptional regulation and mRNA processing respectively, as potential candidates. Further studies will elucidate the role of these factors on lacO/LacI induced silencing. ADN Chromatine Replication Levure à bourgeon Protein-DNA Budding yeast 572.86
13	Identification of New Genes Involved in Meiosis by a Genetic Screen Banerjee, Sneharthi 13 August 2013 (has links) No description available. Genetics Budding yeast meiosis screen ZMM temperature-sensitive phenotype
14	Visualization of the Budding Yeast Cell Cycle Cui, Jing 31 July 2017 (has links) The cell cycle of budding yeast is controlled by a complex chemically reacting network of a large group of species, including mRNAs and proteins. Many mathematical models have been proposed to unravel its molecular mechanism. However, it is hard for people with less training to visually interpret the dynamics from the simulation results of these models. In this thesis, we use the visualization toolkit D3 and jQuery to design a web-based interface and help users to visualize the cell cycle simulation results. It is essentially a website where the proliferation of the wild-type and mutant cells can be visualized as dynamical animation. With the help of this visualization tool, we can easily and intuitively see many key steps in the budding yeast cell cycle procedure, such as bud emergence, DNA synthesis, mitosis, cell division, and the current populations of species. / Master of Science / The cell cycle of budding yeast is controlled by a complex chemically reacting network. Many mathematical models have been proposed to unravel its molecular mechanism. However, it is hard to visually interpret the dynamics from the simulation results of these models. In this thesis, we use the visualization toolkit D3 and jQuery to design a web-based interface and help users to visualize the cell cycle simulation results. It is essentially a webpage where the proliferation of the wild-type and mutant cells can be visualized as dynamical animation. Budding yeast cell cycle Deterministic model MUTANTS HYBRID MODEL VISUALIZATION
15	Fusion of Inverted Repeats Leads to Formation of Dicentric Chromosomes that Cause Genome Instability in Budding Yeast Kaochar, Salma January 2010 (has links) Large-scale changes are common in genomes, and are often associated with pathological disorders. In the work presented in this dissertation, I provide insights into how inverted repeat sequences in budding yeast fuse during replication. Fusion leads to the formation of dicentric chromosomes, a translocation, and other chromosomal rearrangements.Using extensive genetics and some molecular analyses, I demonstrate that dicentric chromosomes are key intermediates in genome instability of a specific chromosome in budding yeast. I provide three pieces of evidence that is consistent with this conclusion. First, I detect a recombination fusion junction that is diagnostic of a dicentric chromosome (using a PCR technique). Second, I show a strong correlation between the amount of the dicentric fragment and the frequency of instability of the entire chromosome. Third, I demonstrate that a mutant known to stabilize dicentric chromosomes suppress instability. Based on these observations, I conclude that dicentric chromosomes are intermediates in causing genome instability in this system.Next, we demonstrate that fusion of inverted repeats is general. Both endogenous and synthetic nearby inverted repeats can fuse. Using genetics, I also show that many DNA repair and checkpoint pathways suppress fusion of nearby inverted repeats and genome instability. Based on our analysis, we propose a novel mechanism for fusion of inverted repeats that we term `faulty template switching.'Lastly, I discuss two genes that are necessary for fusion of nearby inverted repeats. I identified a mutant of the Exonuclease 1 (Exo1) and a mutant of anaphase inhibitor securin (Pds1) that suppress nearby inverted repeat fusion and genome instability. Studies of Exo1 and Pds1 provide us with insights into the molecular mechanisms of fusion.Our finding that nearby inverted repeats can fuse to form dicentric chromosomes that lead to genome instability may have great implications. The generality of this fusion reaction raises the possibility that dicentric chromosomes formed by inverted repeats can lead to genome instability in mammalian cells, and thereby contribute to a cancer phenotype. budding yeast checkpoint Dicentric chromosome faulty template switch Genome rearrangements Inverted repeats
16	Identification of a Genetic Network in the Budding Yeast Cell Cycle / Identifiering av ett gennätverk i jästcellcykeln Fransson, Martin January 2004 (has links) <p>By using AR/ARX-models on data generated by a nonlinear differential equation system representing a model for the cell-cycle control system in budding yeast, the interactions among proteins and thereby also to some extent the genes, are sought. A method consisting of graphical analysis of differences between estimates from two local linear models seems to make it possible to separate a set of linear equations from the nonlinear system. By comparing the properties of the estimations in the linear equations a set of approximate equations corresponding well to the real ones are found. </p><p>A NARX model is tested on the same system to see whether it is possible to find the dependencies in one of the nonlinear differential equations. This approach did, for the choice of model, not work.</p> Reglerteknik Genetic network Budding yeast cell Auto regression State-space model Reglerteknik Automatic control Reglerteknik
17	Deciphering the Role of Aft1p in Chromosome Stability Hamza, Akil 25 January 2012 (has links) The Saccharomyces cerevisiae iron-responsive transcription factor, Aft1p, has a well established role in regulating iron homeostasis through the transcriptional induction of iron-regulon genes. However, recent studies have implicated Aft1p in other cellular processes independent of iron-regulation such as chromosome stability. In addition, chromosome spreads and two-hybrid data suggest that Aft1p interacts with and co-localizes with kinetochore proteins, however the cellular implications of this have not been established. Here, we demonstrate that Aft1p associates with the kinetochore complex through Iml3p. Furthermore, we show that Aft1p, like Iml3p, is required for the increased association of cohesin with the pericentromere and that aft1Δ cells display sister chromatid cohesion defects in both mitosis and meiosis. Our work defines a new role for Aft1p in the sister chromatid cohesion pathway. Aft1 Iml3 kinetochore cohesion cohesin centromere chromosome stability Ctf19 Chl4 Scc1 mitosis meiosis Rec8 budding yeast
18	Deciphering the Role of Aft1p in Chromosome Stability Hamza, Akil 25 January 2012 (has links) The Saccharomyces cerevisiae iron-responsive transcription factor, Aft1p, has a well established role in regulating iron homeostasis through the transcriptional induction of iron-regulon genes. However, recent studies have implicated Aft1p in other cellular processes independent of iron-regulation such as chromosome stability. In addition, chromosome spreads and two-hybrid data suggest that Aft1p interacts with and co-localizes with kinetochore proteins, however the cellular implications of this have not been established. Here, we demonstrate that Aft1p associates with the kinetochore complex through Iml3p. Furthermore, we show that Aft1p, like Iml3p, is required for the increased association of cohesin with the pericentromere and that aft1Δ cells display sister chromatid cohesion defects in both mitosis and meiosis. Our work defines a new role for Aft1p in the sister chromatid cohesion pathway. Aft1 Iml3 kinetochore cohesion cohesin centromere chromosome stability Ctf19 Chl4 Scc1 mitosis meiosis Rec8 budding yeast
19	Identification of a Genetic Network in the Budding Yeast Cell Cycle / Identifiering av ett gennätverk i jästcellcykeln Fransson, Martin January 2004 (has links) By using AR/ARX-models on data generated by a nonlinear differential equation system representing a model for the cell-cycle control system in budding yeast, the interactions among proteins and thereby also to some extent the genes, are sought. A method consisting of graphical analysis of differences between estimates from two local linear models seems to make it possible to separate a set of linear equations from the nonlinear system. By comparing the properties of the estimations in the linear equations a set of approximate equations corresponding well to the real ones are found. A NARX model is tested on the same system to see whether it is possible to find the dependencies in one of the nonlinear differential equations. This approach did, for the choice of model, not work. Reglerteknik Genetic network Budding yeast cell Auto regression State-space model Reglerteknik Automatic control Reglerteknik
20	Functional interactions of chromosome segregation factors with the 2 micron plasmid : possible evolutionary link between the plasmid portioning locus and the budding yeast centromere Huang, Chu-Chun 01 June 2011 (has links) The 2 micron plasmid of Saccharomyces cerevisiae is a multi-copy circular DNA genome that resides in the nucleus and exhibits nearly chromosome-like stability in host populations. Several host factors are required for equal plasmid segregation during cell division. One of them is cohesin (a multi-subunit protein complex) which mediates sister chromatid cohesion, a crucial mechanism for faithful segregation of replicated chromosomes in eukaryotes. The 2 micron plasmid mimics chromosomes in assembling cohesin at its partitioning locus. Studies on minichromosomes (centromere containing plasmids) reveal that cohesin forms a ring that embraces replicated sister centromeres topologically rather than physically. The functional similarities between chromosome and plasmid segregation prompted us to examine whether the topological mechanism proposed for centromere-mediated replicative cohesion is also true in the case of the plasmid. In the present study, we have characterized the nature and stoichiometry of cohesin's association with the 2 micron plasmid. Another host factor required for equal plasmid segregation is the CenH3 histone variant Cse4, so far considered to be uniquely associated with centromeric nucleosomes. Cse4 provides an epigenetic landmark at centromeres, and is required for assembly of the kinetochore complex. Surprisingly, Cse4 also interacts with the 2 micron plasmid partitioning locus. We have now functionally characterized this interaction, which can be preserved even in an ectopic, chromosomal context. The steady state level of Cse4 is highly limiting in yeast due to ubiquitin-mediated proteolysis. Only centromere-associated Cse4 is protected from this regulatory turnover control. We find that, in contrast to the situation with centromeres, association of Cse4 with the 2 micron plasmid is highly sub-stoichiometric but still promotes equal plasmid segregation. We also find that Cse4 induces an unusual right handed DNA writhe at the plasmid partitioning locus, as it does at the centromere. Our findings suggest that the plasmid has designed strategies to minimize the utilization of host factors that are in short supply. They signify the advantage of clustering and group behavior in the evolutionary success of a multi-copy selfish genome. Finally, they also suggest the possible emergence of the yeast centromere and the plasmid partitioning locus from a common ancestral sequence. / text Plasmid segregation Chromosome segregation Selfish DNA Budding yeast Saccharomyces Cohesin Cse4 Centrosomes Plasmids

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