Global ETD Search

91	Biologický význam fosforylace tyrosinu 90 v SH3 doméně kinázy Src / Biological relevance of the tyrosine 90 phosphorylation in SH3 domain Src kinase Koudelková, Lenka January 2013 (has links) Kinase Src plays an essential role in signal transduction from activated surface receptors. Src is involved in signal pathways that participate in the control of cell proliferation, differentiation or motility. That is why Src activation undergoes strict and complex regulation. Inactive conformation is maintained by intramolecular inhibitory interactions. SH3 domain associates with a polyprolin helix in CD linker whereas SH2 domain binds phosphorylated C-terminal tyrosine 527. Both regulatory domains maintain contacts with the lobes of a kinase domain thereby stabilizing an inactive conformation of the catalytic domain. Transition to an active state is accompanied by a disruption of these inhibitory interactions. Conformation changes are substantially influenced by the phosphorylation status of key tyrosines 416 and 527. Phosphoproteomic analysis revealed new Src tyrosine residue, which can be phosphorylated in vivo. It has been found, that tyrosine works as an additional regulator of Src activity. This is Tyr 90, which forms one of the hydrophobic pockets in the binding surface of Src SH3 domain. Based on the expression of phosphomimic mutant Src 90E in S. pombe or in SYF lineage, it has been observed, that Tyr 90 phosphorylation elevates Src kinase activity. The reason is that the phosphate...
92	Characterization of two domains of Schizosaccharomyces pombe adenylate cyclase Baum, Kristen Michelle January 2005 (has links) Thesis advisor: Charles S. Hoffman / Glucose detection in yeast occurs via a cAMP signaling pathway that is similar to that of other signaling pathways in humans. The presence of glucose in the environment ultimately represses, as a result of cAMP signaling, the transcription of the gene fbp1. Adenylate cyclase is known to convert ATP to cAMP, and is thus a central protein in the propagation of the signal. Mutant forms of the adenylate cyclase gene (git2) have been found by the inability for the organism to repress fbp1 transcription in the presence of glucose. In this study, two questions were under investigation. The first was focused on the ability of the mutations to affect the dimerization of the catalytic domain. The second investigated multiple protein-protein interactions in the leucine rich-repeat (LRR) domain of adenylate cyclase. Both domains contain mutations that confer an activation defect, and they are thus are thought to have a relationship. / Thesis (BS) — Boston College, 2005. / Submitted to: Boston College. College of Arts and Sciences. / Discipline: Biology. / Discipline: College Honors Program. Biology, Genetics adenylate cyclase Schizosaccharomyces pombe leucine rich repeat cAMP signaling G-protein signaling two-hybrid screen
93	Functions of the Cdc14-Family Phosphatase Clp1p in the Cell Cycle Regulation of <em>Schizosaccharomyces pombe</em>: A Dissertation Trautmann, Susanne 20 May 2005 (has links) In order to generate healthy daughter cells, nuclear division and cytokinesis need to be coordinated. Premature division of the cytoplasm in the absence of chromosome segregation or nuclear proliferation without cytokinesis might lead to aneuploidy and cancer. The cyclin dependent kinases, CDKs, are a main regulator of the cell cycle. Timely increase and decrease in their activity is required for cell cycle progression. To enter mitosis, mitotic CDK activity needs to rise. CDK activity stays elevated until chromosome segregation is completed and exit from mitosis requires decrease in CDK activity. Observations in several experimental systems suggest that coordination of cytokinesis with the nuclear cycle is regulated through CDK activity. Prolonged high CDK activity, as it occurs when chromosome segregation is delayed, was found to oppose cytokinesis. Prevention of cytokinesis through high CDK activity may therefore provide a mechanism to prevent precocious cell division in the absence of chromosome segregation. To prevent polyploidy when cell division is delayed, progression through the next nuclear cycle should be inhibited until cytokinesis is completed, presumably by the inhibition of CDK activity. In the fission yeast Schizosaccharomyces pombe, a signaling cascade called Septation Initiation Network (SIN) is required for the coordination of cytokinesis with the nuclear cycle. The SIN is essential for cytokinesis, triggering the execution of cell division through constriction of the actomyosin ring. The activation of the SIN signaling cascade, and thus cytokinesis, is opposed by high CDK activity, preventing precocious cytokinesis. S. pombe delay entry into the next nuclear division in response to delayed cytokinesis due to defects in the contractile ring until cytokinesis is completed thereby preventing the accumulation of multinucleate, non viable cells. This safeguard against multinucleate cells is termed the cytokinesis checkpoint. The cytokinesis checkpoint keeps CDK activity low, preventing nuclear cycle progression. The SIN is required for the cytokinesis checkpoint and therefore is a key coordinator between nuclear cycle and cytokinesis. How the SIN functions in the cytokinesis checkpoint was not known. Cdc14-family phosphatases are highly conserved from yeast to humans, but were only characterized in Saccharomyces cerevisiae at the time this thesis was initiated. Cdc14 had been identified as the effector of a signaling cascade homologous to the SIN, called the mitotic exit network (MEN), which is required for exit from mitosis. This thesis describes the identification of the S. pombe Cdc14-like phosphatase Clp1p as a component of the cytokinesis checkpoint. Clp1p opposes CDK activity, and Clp1p and the SIN activate each other in a positive feedback loop. This maintains an active cytokinesis checkpoint and delays mitotic entry. We further found that Clp1p regulates chromosome segregation. Concluding, this thesis describes discoveries adding to the characterization of the cytokinesis checkpoint and the function of Clp1p. While others found that Cdc14-family phosphatases, including Clp1p, have similar catalytic functions, we show that their biological function may be quite different between organisms, possibly due to different biological challenges. Cytokinesis Cell Cycle Proteins Gene Expression Regulation Enzymologic Protein-Serine-Threonine Kinases Schizosaccharomyces pombe Proteins Genes cdc Enzymes and Coenzymes Fungi
94	Molecular mechanisms of Tea1 cortical anchoring in Schizosaccharomyces pombe Bicho, Cláudia do Céu Afonso January 2010 (has links) Establishment and maintenacne of a polarized axis is essential for all organisms. Cells can either change their shape in response to extracellular cues or maintain a stable polarity axis via landmarks defined in relation to internal cues. In the fission yeast Schizosaccharomyces pombe,microtubules regulate cortical cell polarity together with the landmark protein Tea1. Tea1 is transported to cell tips on microtubule plus-‐ends and deposited upon microtubule contact with the membrane. Although Tea1 has been shown to interact with several binding-partners, Tea1 anchoring at the cell tip depends mostly on the membrane-associated protein, Mod5. Tea1 and Mod5 accumulate in clusters at the cell tip in a mutually dependent manner. I used a combination of live-‐cell imaging, FRAP (Fluorescence Recovery After Photobleaching) and computational modeling to dissect the dynamics of the Tea1-‐Mod5 interaction. I have shown that although Tea1 is stably associated with the cell tip, Mod5 is mobile within the cell tip. I proposed a model in which Tea1 is stable at the cell tip due to self-‐polymerization and association in the form of a cluster-‐network. In the model, the role of Mod5 in the cluster-‐network is to facilitate the formation of Tea1-‐Tea1 interactions. Moreover, in the model, Mod5 is restricted to the cell tip due to iterative binding to and release from the Tea1 cluster-‐network. The properties of the proposed Tea1 cluster-‐ network might contribute to the behavior of Tea1 as a polarity landmark. I hypothesized that Tea1 transfer from the microtubules to the cell tip was regulated by phosphorylation. Tea1 phosphorylated residues were mapped using mass spectroscopy (MS), and identified to be mostly enriched within a central region of the protein. Using a combination of mutagenic analysis and live-‐cell imaging I demonstrate that Tea1 phosphorylation might be required for its dissociation from the cluster-‐network at the cell tip. This suggests that Tea1 interactions within the cluster network are phospho-‐regulated by one of the several tip-‐localized kinases. It has been shown in other organisms and in this thesis that comparison among MS samples requires quantitative MS methodologies. Thus, I developed a robust SILAC (Stable Isotope Labeling in Cell Culture) method to perform quantitative MS in S. pombe. As a proof-‐of-‐principle of the method I performed a proteome-‐wide comparison between the late G2 and the G1/S transition of the cell cycle. The cell cycle proteome-‐wide analysis not only quantified variation in expression levels of cell cycle regulated proteins but also identified novel cell cycle regulated proteins. It has been previously shown that Tea1, Tea3 and Mod5 can interact simultaneously, with each pair interacting independently of the third protein. I describe here a Mod5 mutagenic analysis screen designed to separate Tea1 and Tea3 binding site on Mod5. The Mod5-‐mutants obtained from this analysis indicate that the Tea3-‐Mod5 interaction may play a role in cell polarity establishment. Moreover, although Tea3 is non-‐essential for the cluster-‐network formation, Tea3 might be important for its compaction, which may be particularly important during de novo formation of cell polarity. 571.6
95	Study of a novel evolutionarily conserved pattern of histone acetylation Rajan, Roshan Elizabeth 12 1900 (has links) No description available. Histones Acétylation Spectrométrie de masse Histone acétyltransférases Histone déacétylases Schizosaccharomyces pombe Mass spectrometry
96	Caractérisation moléculaire et fonctionnelle de Cif1p, une protéine orpheline impliquée dans le phénomène épigénétique de viabilité de la levure S. pombe en absence de la chaperone calnexine. Beauregard, Pascale B. 01 1900 (has links) Le repliement des protéines est un processus cellulaire crucial impliquant plusieurs protéines dont la calnexine, une chaperone du réticulum endoplasmique. Notre laboratoire et un autre groupe avons démontré que la calnexine est essentielle à la viabilité de la levure Schizosaccharomyces pombe. Dans le cadre d’études structure-fonction portant sur cette protéine, nous avons découvert un phénomène permettant la viabilité des cellules en absence de la calnexine. Cet état, nommé Cin pour calnexine independence, est induit par un mutant de la calnexine dépourvu du domaine central hautement conservé (Δhcd_Cnx1p). La caractérisation de l’état Cin a révélé plusieurs caractéristiques particulières telle la dominance, sa transmission de façon non-Mendélienne à la progéniture méïotique et sa transmission par des extraits protéiques dépourvus d’acides nucléiques. Toutes ces propriétés suggèrent donc que l’état Cin est médié via un élément de type prion. Le gène cif1+, pour calnexin independence factor, a été isolé lors de criblages visant à identifier des gènes impliqués dans l’état Cin. Il encode pour une protéine orpheline dont la surexpression induit de façon stable un état de viabilité en l’absence de la calnexine. Cet état diffère génétiquement et phénotypiquement de l’état Cin induit par le mutant Δhcd_Cnx1p préalablement caractérisé, ce qui suggère deux voies parallèles de signalisation du phénomène Cin. Une caractérisation exhaustive de Cif1p a permis de démontrer qu’il ne s’agissait pas du prion responsable de l’état Cin, malgré que cette protéine possède certaines propriétés typiques des prions in vitro. Finalement, Cif1p est une protéine nucléolaire dont la bonne localisation est essentielle à sa capacité à induire l’état Cin. Ceci suggère une interaction entre la fonction essentielle de la calnexine et une fonction exécutée dans le nucléole. Lors d’études visant à élucider la fonction cellulaire de Cif1p, il a été établi qu’elle interagissait avec certaines protéines de la grosse sous-unité du ribosome telle la protéine L3. Cependant, Cif1p ne co-sédimente pas avec des sous-unités ribosomales assemblées, des ribosomes ou des polysomes. De plus, des cellules contenant une délétion génomique de cif1 voient leur contenu en ribosomes perturbé lors de la phase stationnaire. Il semble donc que Cif1p joue un rôle dans la biosynthèse des ribosomes lors de la phase stationnaire. Ce rôle spécifique à cette phase de croissance coincide avec un clivage de la portion N-terminale de Cif1p, clivage qui a lieu lors de l’entrée des cellules en phase stationnaire. De plus, des études effectuées récemment dans notre laboratoire proposent que la calnexine joue un rôle important dans la signalisation de l’apoptose, et ce particulièrement en phase stationnaire. Ainsi, une voie impliquant Cif1p, sa fonction nucléolaire dans la biosynthèse des ribosomes en phase stationnaire, la calnexine et la médiation de l’apoptose semble se dessiner. D’autres travaux, notamment sur la fonction exacte de Cif1p, le rôle de son clivage et les autres composantes impliquées dans le phénomène Cin nous permettront de dessiner un portrait plus complet de cette voie cellulaire inédite. / Protein folding is a vital process that involves many proteins of the cell. One of them is calnexin, a chaperone of the endoplasmic reticulum. In the fission yeast Schizosaccharomyces pombe, calnexin is essential for survival of the cells. During structure-function studies on calnexin, our laboratory discovered a phenomenon allowing the viability of cells without this chaperone. This state, designated Cin for Calnexin INdependence, is induced by a calnexin mutant devoid of the highly conserved central domain (Δhcd_Cnx1p). Characterization of the Cin cells showed several exceptional properties such as dominance, non-Mendelian transmission and transmission via cell extracts devoid of nucleic acids of the Cin state. All these observations suggested that the Cin phenomenon is mediated via a prionic element. To identify genes implicated in the Cin state, genetic screens were performed. They led to the identification of the cif1+ gene, for calnexin independence factor. This gene encodes an orphan protein, the overexpression of which stably induces a state of viability in the absence of calnexin. Notably, this state is genetically and phenotypically distinct from the previously isolated Cin state arising from Δhcd_Cnx1p expression. This suggests the presence of two parallel pathways both able to signal the induction of the Cin phenomenon. The exhaustive characterization of Cif1p showed that it is not the prion solely responsible for the Cin state, although it displays prion-like properties in vitro. Finally, nucleolar localization of Cif1p is required to induce the Cincif1 state, thus suggesting an unexpected interaction between the vital cellular role of calnexin and a function of the nucleolus. While investigating Cif1p function in the cell, we observed that it interacts with ribosomal proteins of the large subunit, notably L3, but it does not sediment with assembled ribosomal subunits or whole ribosomes. However, cells containing a genomic deletion of cif1 also have a disrupted ribosome content during stationary phase. Altogether, these results suggest that Cif1p has a role in ribosomal biogenesis during stationary phase. This growth-phase specific role correlates with the occurence during stationary phase of a cleavage in the N-terminal part of Cif1p. Recent studies from our laboratory proposed that calnexin plays an important role in apoptosis signaling, especially in stationary phase. Thus, a pathway implicating Cif1p, its nucleolar function in ribosome biosynthesis in stationary phase, calnexin and apoptosis signaling is starting to emerge. However more studies, notably on the exact function of Cif1p, the role of its cleavage and the other proteins implicated in the Cin state will be necessary to draw the complete scheme of this unprecedented cellular pathway. Chaperone Calnexine Schizosaccharomyces pombe Nucléole Ribosome Phase stationnaire Calnexin Nucleolus Prion Stationnary phase
97	Role of the stress-dependent MAP kinase Sty1 and the transcription factor Atf1 in transcription regulation in fission yeast Sansó Martínez, Miriam 02 July 2010 (has links) In Schizosaccharomyces pombe, the MAPK pathway Sty1 is activated upon several stress situations, like osmotic and oxidative stress, stationary phase, UV radiation or heat shock. Since the modulation of gene expression is one of the main outputs of this response, we focused this Thesis work on the charactherization of the transcription regulation by the activation of the Sty1 pathway and through the transcription factors Atf1 and Pcr1. Moreover, we extend our field of interest investigating how stress–related chromatin remodelers are affecting the stress defence transcription of the cells. / En Schizosaccharomyces pombe, la vía de la MAPK Sty1 es activada ante diferentes situaciones de estrés, como son el estrés oxidativo u osmótico, fase estacionaria, radiación UV o choque de calor. Al ser la modulación de la expresión génica uno de los más importantes objetivos de esta respuesta, hemos focalizado el trabajo de esta Tesis doctoral en la caracterización de la regulación transcripcional mediada por la activación de la ruta de Sty1 y los factores de transcripción Atf1 y Pcr1. Además, hemos ampliado nuestra área de interés investigando el papel de remodeladores de cromatina relacionados con la respuesta a estrés y cómo a participan en la transcripción estrés-dependiente. Schizosaccharomyces pombe Estrés ambiental Factor de transcripción RNA-polimerasa II Gcn5 Sin3 Atf1 Signal transduction Pcr1 Sty1 57
98	Functional characterisation of conserved checkpoint genes Kanter Smoler, Gunilla. January 1998 (has links) Th. : Göteborg : 1998. / Notes bibliogr.
99	Caractérisation moléculaire et fonctionnelle de Cif1p, une protéine orpheline impliquée dans le phénomène épigénétique de viabilité de la levure S. pombe en absence de la chaperone calnexine Beauregard, Pascale B. 01 1900 (has links) No description available. Chaperone Calnexine Schizosaccharomyces pombe Nucléole Ribosome Phase stationnaire Calnexin Nucleolus Prion Stationnary phase
100	Elucidation of the Multi-Faceted Roles of the SIN (Septation Initiation Network); Understanding How the SIN Promotes Cytokinesis and Inhibits Interphase Growth in the Fission Yeast Schizosaccharomyces pombe: A Dissertation Ray, Samriddha 17 August 2010 (has links) Cytokinesis is the cytoplasmic division of one cell into two independent daughter cells. Precise regulation of cytokinesis during cell cycle is essential for healthy and rapid multiplication of any organism. Schizosaccharomyces pombe has emerged as an excellent model system to study eukaryotic cell division regulation. This rod shaped organism grows by bipolar elongation in interphase when its actin cytoskeleton is concentrated at the cell ends (poles). However, growth stops in mitosis and the actin cytoskeleton is rearranged to facilitate assembly of the contractile actomyosin ring at the cell middle. Although several studies have focused on the separate processes of growth and division, it was unclear how cells regulate the cytoskeletal remodeling during the transition between the different stages of the cell cycle. The Septation Initiation Network (SIN) is a signaling cascade essential for fission yeast cytokinesis (Balasubramanian et al., 1998; Mishra et al., 2004) and the MOR (morphogenesis) signaling pathway is essential for interphase bipolar growth (Kanai et al, 2005). Interestingly, inactivation of the SIN not only failed to maintain the cytokinetic apparatus at the cell middle but also caused the redistribution of the cytoskeletal elements like actin to the cell ends that led to bipolar cell elongation similar to cells in interphase (Mishra et al., 2004). These results suggested that SIN signaling inhibits interphase bipolar growth, but it was not clear if the SIN had a direct role in inhibition of interphase growth during mitosis and this question was the major focus of this thesis. The results presented in Chapter II show a novel cross-pathway interaction between the SIN and the MOR in the fission yeast. Our results in Chapter III suggest that some of the MOR pathway components might be important for coordination between nuclear and cytoplasmic divisions in mitosis, revealing novel roles of the pathway. In a separate study (Chapter IV) we sought to identify additional regulators of the SIN and cytokinesis through a suppressor screen and found that the nucleolar rDNA transcription machinery inhibits cytokinesis in fission yeast. Cytokinesis Schizosaccharomyces pombe Proteins Signal Transduction Amino Acids, Peptides, and Proteins Cell and Developmental Biology Cells Fungi Genetic Phenomena

Search results