Global ETD Search

321	Etude de la polarité apico-basale dans les cellules épithéliales et son implication dans le cholangiocarcinome intrahépatique : contribution de l'inositol 5-phosphatase SHIP2 / Study of apico-basal polarity in epithelial cells and its implication in intrahepatic cholangiocarcinoma : contribution of inositol 5-phosphatase SHIP2 Hamze komaiha, Ola 26 January 2017 (has links) La polarité cellulaire est un déterminant essentiel dans le maintien de l’architecture tissulaire et la fonction de l’organe. Ainsi, la division cellulaire, la ciliogenèse, la prolifération, et la migration sont des évènements étroitement associés au processus de la polarisation cellulaire. L’altération de la polarité cellulaire contribue à la perte de l’intégrité des épithéliums et favorise le développement des cancers. La signalisation des lipides, telle que des phosphatidylinositols (PtdIns) joue un rôle vital dans la polarité apico-basale. Dans cette étude, nous avons développé des recherches pour mieux comprendre les mécanismes impliqués dans les effets de la phosphatase SHIP2 sur la polarité cellulaire. Nous avons pu démontrer que SHIP2 est impliquée dans la formation du site d’initiation de la formation de la lumière (AMIS) en régulant d’une part la contractilité acto-myosine induite par RhoA kinase et d’autre part YAP, un composant de la voie de signalisation Hippo. De plus, nous avons montré que l'inhibition de SHIP2 contribue à un défaut dans la formation de fuseau mitotique et dans le clivage de ce fuseau mitotique. La surexpression de SHIP2 induit une lumière large et des cils allongés attribuables à la diminution de l’expression de YAP, Aurora A et HEF1. Par contre, la diminution de l’expression de SHIP2 inhibe la formation des cils en provoquant la surexpression de YAP, Aurora A et HEF1 et ainsi l’apparition d’un phénotype multilumens. L’ensemble de nos travaux définissent un nouveau rôle de SHIP2 dans le maintien de l’intégrité et de l’homéostasie des cellules épithéliales. Nous avons aussi pu démontrer que l’expression de SHIP2 peut discriminer les différents cancers du foie (HCC, ICC et mixte) et que SHIP2 et Merlin/NF2, une protéine de la voie de signalisation Hippo, ont une forte expression dans le cholangiocarcinome (ICC) qui s’oppose à celle de YAP et de RhoA kinase. / Cell polarity is critical caracteristic for the maintenance of tissue architecture. Cell division, ciliogenesis, cell proliferation and migration are events tightly associated to cell polarization processes. Alteration in cell polarity contributes to loss of epithelium integrity and enhances cancer development. Lipids signaling, such as phosphatidylinositol (PtdIns), play a vital role in apico-basal polarity. In this study, we developed researches to better understand mechanisms implicated the role of the phosphatase SHIP2 in cell polarity. We demonstrated that SHIP2 is implicated in formation of the apical membrane initiation site (AMIS) by regulating YAP, a component of Hippo pathway, and RhoA-dependant acto-myosin contractility. Furthermore, we demonstrated that inhibition of SHIP2 contributes to defect in the formation and cleavage of the mitotic spindle. Overexpression of SHIP2 induced a large lumen with long cilia due to a decrease in YAP, Aurora A and HEF1 luminal localization. On the contrary, down regulation of SHIP2 impaired cilia outgrowth by increasing Aurora A, HEF1 and YAP luminal localization with appearance of a multilumens phenotype. Thus, our results reinforced the role of SHIP2 in maintain of integrity and homeostasis of epithelial cells. In this study, we also demonstrated that expression of SHIP2 distinguished the different types of liver cancer (HCC, ICC and mixte), and that SHIP2 and Merlin/NF2 are overexpressed in ICC which is the opposite of YAP and RhoA expression. Ship2 Polarité cellulaire Aurora A et HEF1 Ciliogenèse Division cellulaire La voie Hippo/YAP Ship2 Cell polarity Aurora A and HEF1 Ciliogenesis Cell division Hippo/YAP pathway
322	New Insights into the Cell Biology of Hematopoietic Progenitors by Studying Prominin-1 (CD133) Bauer, Nicola, Fonseca, Ana-Violeta, Florek, Mareike, Freund, Daniel, Jászai, József, Bornhäuser, Martin, Fargeas, Christine A., Corbeil, Denis January 2008 (has links) Prominin-1 (alias CD133) has received considerable interest because of its expression by several stem and progenitor cells originating from various sources, including the neural and hematopoietic systems. As a cell surface marker, prominin-1 is now used for somatic stem cell isolation. Its expression in cancer stem cells has broadened its clinical value, as it might be useful to outline new prospects for more effective cancer therapies by targeting tumor-initiating cells. Cell biological studies of this molecule have demonstrated that it is specifically concentrated in various membrane structures that protrude from the planar areas of the plasmalemma. Prominin-1 binds to the plasma membrane cholesterol and is associated with a particular membrane microdomain in a cholesterol-dependent manner. Although its physiological function is not yet determined, it is becoming clear that this cell surface protein, as a unique marker of both plasma membrane protrusions and membrane microdomains, might reveal new aspects of the cell biology of rare stem and cancer stem cells. The aim of this review is to outline the recent discoveries regarding the dynamic reorganization of the plasma membrane of rare CD133+ hematopoietic progenitor cells during cell migration and division. / Dieser Beitrag ist mit Zustimmung des Rechteinhabers aufgrund einer (DFG-geförderten) Allianz- bzw. Nationallizenz frei zugänglich. info:eu-repo/classification/ddc/610 ddc:610
323	Min-Protein Waves on Geometrically Structured Artificial Membranes Schweizer, Jakob 06 February 2013 (has links) Das stäbchenförmige Bakterium Escherichia coli teilt sich in zwei gleich große Tochterzellen. Dies ist nur möglich, wenn sich die Zelle in der Mitte teilt. Bei E. coli wird die Zellteilung durch den Zusammenschluss der FtsZ-Proteine an der Membran zum Z-Ring eingeleitet. Topologische Regulierung des Z-Ringes erfolgt durch räumlich-zeitliche Oszillationen von Min-Proteinen zwischen den beiden Zellpolen. MinC, MinD und MinE binden an und lösen sich von der Membran unter Hydrolyse von ATP und in antagonistischer Art und Weise, was zu einer alternierenden Ansammlung von MinC und MinD an den Zellpolen führt. Gemittelt über die Zeit ergibt sich somit ein MinD-Verteilungsprofil, das maximale Konzentration an den Zellpolen und ein Minimum in der Zellmitte aufweist. MinC bindet an MinD und folgt somit seiner Verteilung. Der Zusammenschluss von FtsZ-Proteinen wird durch MinC unterbunden, und somit kann sich der Z-ring nur an einer Position herausbilden, die ein Minimum an MinC aufweist - der Zellmitte. Das Min-system wurde in der Vergangenheit auch mit einem in-vitro-Ansatz untersucht, indem Min-Proteine in künstliche, aufliegende Lipiddoppelschichten (supported lipid bilayers, SLB) rekonstitutiert wurden. Dabei bildeten die Min-Proteine kein oszillierendes Muster aus, sondern organisierten sich vielmehr in parallelen und propagierenden Wellen (Loose, 2008, Science, 320). In diesen in-vitro-Experimenten war das Membransubstrat wesentlich größer als die Wellenlänge der Min-Proteinwellen. In vivo hingegen ist die Länge der Zelle in der gleichen Größenordnung wie die charakteristische Länge des Oszillationsmusters der Min-Proteine. Daher war es das Ziel dieser Arbeit, den Einfluß einer beschränkten Fläche und geometrischer Formgebung der künstlichen Lipiddoppelschichten auf die Wellenpropagation der Min-Protein zu untersuchen. Flächige Beschränkung künstlicher Membranen erfolgte durch Mikrostrukturtechnologie. Deckglässchen wurden mit einer Goldschicht und mikroskopischen Aussparungen unterschiedlicher geometrischer Formen strukturiert. Funktionale SLBs bildeten sich nur auf Glasflächen ohne Goldbeschichtung aus. Nach der Rekonstitution der Min-Proteine, organisierten sich diese auf den Membranstücken in parallele Wellen. Dabei bestimmte die flächige Beschränkung der künstlichen Membranen die Ausbreitungsrichtung der Min-Proteinwellen. Min-Proteinwellen konnten entlang gekrümmter Membranstreifen, in Ring- und sogar in Slalomstrukturen geleitet werden. In geraden, länglichen Strukturen richteten sich die Wellen entlang der längsten Achse aus. Kopplung von Proteinwellen auf räumlich getrennten Membranstücken in Abhängigkeit des Abstandes und des sogenannten Molecular Crowdings in der wässrigen Lösung konnte ebenfalls beobachtet werden. Diese Kopplung ist ein Indiz für inhomogene Proteinverteilungen in der Lösung oberhalb der Membran. Desweiteren konnten Min-Proteinwellen auch in diversen dreidimensionalen künstlichen Membranen rekonstitituiert werden. Im Wildtyp von E. coli ähneln die Min-Proteindynamiken der einer Oszillation mit einer charakteristischen Länge von 5 µm. Auf SLBs, bilden Min-Proteine Wellen mit einer Wellenlänge aus, die ca. zehnmal größer ist als in vivo. Dieser Unterschied zwischen der in-vivo- und der in-vitro-Welt wurde untersucht und diskutiert. In vitro konnte die Wellenlänge um 50 % durch Erhöhung des Molecular Crowding in der Lösung sowie um 33 % durch Temperaturerhöhung verkleinert werden. Das oszillierende Muster könnte dahingegen eine Folge der Kompartimentierung sein. Erste Versuche, das Min-System in geschlossene Membrankompartimente zu rekonstitutieren, wurden getestet. / Escherichia coli, a rod-like bacterium, divides by binary fission. Cell division into two daughter cells of equal size requires that fission takes place at a midcell position. In E. coli, cell division is initiated by assembly of the FtsZ-proteins at the inner membrane to the Z-ring. Topological regulation of the Z-ring is achieved by spatiotemporal pole-to-pole oscillations of Min-proteins. MinC, MinD and MinE bind to and detach from - under hydrolysis of ATP - the membrane in an antagonistic manner leading to an alternating accumulation of MinC and MinD at the cell poles. Averaged over time, the distribution profile of MinD exhibits maximal concentration at the cell poles and a minimum at the cell center. MinC binds to MinD and thus follows its distribution. FtsZ assembly is inhibited by MinC and therefore the Z-ring can only form at a cell position low in MinC - at the cell center. In the past, the Min-system was also investigated in an in vitro approach by reconstitution of Min-proteins into a supported lipid bilayer (SLB). Here, Min-proteins did not self-organize into an oscillatory pattern but into parallel and propagating waves (Loose, 2008, Science, 320). In this in vitro assay, the membrane substrate was infinitely large compared to the wavelength. However, in vivo, the cell length is on the same order of magnitude as the respective length scale of the oscillatory pattern of Min-proteins. Therefore, we wished to investigate the effect of lateral confinement and geometric structuring of artificial lipid bilayers on the Min-protein wave propagation. Lateral confinement of artificial membranes was achieved by microfabrication technology. Glass slides were patterned by a gold coating with microscopic windows of different geometries, and functional SLBs were only formed on uncoated areas. Upon reconstitution, Min-proteins organized into parallel waves on the geometric membrane patches. Confinement of the artificial membranes determined the direction of propagation of Min-protein waves. Min-protein waves could be guided along curved membrane stripes, in rings and even along slalom-geometries. In elongated membrane structures, the protein waves always propagate along the longest axis. Coupling of protein waves across spatially separated membrane patches was observed, dependent on gap size and level of molecular crowding of the aqueous media above the bilayer. This indicates the existence of an inhomogeneous and dynamic protein gradient in the solution above the membrane. Furthermore, reconstitution of Min-protein waves in various three-dimensional artificial membranes was achieved. In wild-type E. coli, Min-protein dynamics resemble that of an oscillation with a characteristic length scale of 5 µm. On supported lipid bilayers, Min-proteins self-organize into waves with a wavelength approximately 10-fold larger than in vivo. These discrepancies between the in vivo and in vitro world were investigated and discussed. In vitro, the wavelength could be decreased by a factor of 50 % by increase of the molecular crowding in solution and by 33 % through temperature increase. The oscillatory pattern is thought to be a consequence of compartmentalization and first attempts to encapsulate the Min-system in closed bilayer compartments are presented. info:eu-repo/classification/ddc/570 ddc:570
324	Analýza signální dráhy proteinkinasy StkP u Streptococcus pneumoniae / Analysis of signaling cascade of protein kinase StkP in Streptococcus pneumoniae Holečková, Nela January 2020 (has links) Analysis of signaling cascade of protein kinase StkP in Streptococcus pneumoniae Streptococcus pneumoniae is not only an important human pathogen but also an appropriate model organism to investigate cell division in ovoid bacteria. This bacterium lacks both, NO and Min systems for selection of cell division site. Thus, the mechanism which determines the site of cell division is unknown. Additionally, the genome of S. pneumoniae encodes a single gene for eukaryotic-like serine/threonine protein kinase StkP and a single gene for eukaryotic-like serine/threonine protein phosphatase of PP2C type called PhpP. StkP is one of the main regulators of cell division. Cell division is probably affected by the phosphorylation of its substrates, which include, among others, cell division proteins FtsZ, FtsA, DivIVA, MacP, Jag/KhpB/EloR, and LocZ/MapZ. The aim of the first project of this dissertation thesis is determination of the function of protein LocZ in the cell division. In summary, locZ is not essential, however, it is involved in proper septum placement in S. pneumoniae and our data suggest that it is a positive regulator of Z-ring placement. Cells lacking LocZ are able to form Z-ring, but the Z-ring is spatially misplaced resulting in cell division defects, shape deformation, and generation of unequally sized,...
325	REGULATION AND FUNCTION OF HAM GENES AND MERISTEM DEVELOPMENT IN CERATOPTERIS RICHARDII Yuan Geng (12455814) 25 April 2022 (has links) <p> </p> <p>The growth of land plants depends on a group of pluripotent stem cells in a tissue called the meristem. Seed plants initiate and maintain different types of meristems at the asexual sporophyte stage, and they generate sexual gametophytes, which are dependent on their sporophytes and are devoid of a meristem. In contrast, aside from forming indeterminate meristems at the sporophyte stage, seedless vascular plants, including ferns, also develop meristems in their gametophytes to drive gametophyte development and formation of sexual organs. To date, compared to the well-characterized cell behaviors and regulatory pathways in the meristems of seed plants, the molecular and cellular basis of meristem development in seedless ferns is still poorly understood. </p> <p>In several seed plants, the HAIRY MERISTEM (HAM) family transcription factors play important roles in maintaining the indeterminacy of shoot apical meristems and promoting the <em>de novo</em> formation of axillary meristems. In the first part of this dissertation, through constructing a comprehensive phylogeny, I found that HAM family members are widely present in land plants and duplicated in a common ancestor of flowering plants, leading to the formation of two distinct groups: type I and type II. In addition, HAM members from different seed plants and seedless plants are able to replace the roles of the Arabidopsis type-II <em>HAM</em> genes, maintaining established shoot apical meristems and promoting the initiation of new stem cell niches in Arabidopsis. Furthermore, preliminary functional studies of the <em>HAM </em>homolog (<em>CrHAM</em>) in the model fern<em> Ceratopteris richardii</em> suggest that CrHAM is required for maintaining the indeterminacy of multicellular meristems in Ceratopteris gametophytes. Collectively, these results indicate that HAM family members may serve as common regulators in control of meristem development in both seed plants and seedless vascular plants. </p> <p>In the remaining chapter of this dissertation, long-term time-lapse confocal imaging was performed using Ceratopteris stable transgenic plants, in which each individual cell (nucleus) was labelled with a fluorescent marker. Real-time lineage, identity, and division activity of each single cell from meristem initiation to establishment in Ceratopteris gametophytes were then determined. Additionally, cell fate and lineage alterations during <em>de novo</em> formation of new meristems were examined by mechanical perturbations. These quantitative analyses lead to the conclusion that in Ceratopteris gametophytes, initiation and proliferation of multicellular meristems relies on a few marginal cell lineages. Once established, the meristem maintains an actively dividing zone during gametophyte development. Within the meristem, cell division is independent of cell lineages and marginal cells are more actively dividing than inner cells. The meristem also triggers differentiation of adjacent cells into egg-producing archegonia in a position-dependent manner. </p> <p>In summary, this work provides insight into the evolution of key stem-cell regulators and advances the understanding of diversified meristem development in land plants. </p> Molecular Biology Plant Biology Stem Cells Molecular Evolution Meristems Ferns Cell division Stem cells Transcription factors Gametophyte development Cell lineage Land plants
326	Mdm2 and Mdm4 Functions in Growth Control: a Dissertation Steinman, Heather Anne 01 June 2004 (has links) Amplification and/or overexpression of the Mdm2 oncogene occurs in many human cancers. Mdm2 promotes cellular proliferation, interferes with apoptosis, and induces tumor formation through the negative regulation of the p53 tumor suppressor. More than thirty percent of human tumors overexpressing Mdm2 also present with alternatively spliced Mdm2 isoforms that cannot directly bind p53. The presence of Mdm2 isoforms in tumors correlates with a higher tumor grade and a poorer prognosis for the patient. To investigate the function of Mdm2 isoforms in tumorigenesis, we have isolated a number of Mdm2 splice forms from tumors obtained from Mdm2-transgenic mice and find that the most frequently observed splice form in human tumors, Mdm2-b, is conserved in mice. Although the Mdm2-b protein is incapable of binding to p53 and is unable to localize to the nucleus, we demonstrate that Mdm2-b promotes cell growth in NIH3T3 cells, Rb-deficient, p19-deficient, and p53-deficient primary cells. We also show that Mdm2-b inhibits apoptosis in response to serum withdrawal and restimulation, doxorubicin treatment, and TNF-alpha administration. Mdm2-b induces foci formation in vitro and directly contributes to tumor formation in GFAP-Mdm2 transgenic mice. We propose that Mdm2-b promotes tumor growth by upregulating RelA (P65) protein levels and activity in a p53-independent manner. To better understand additional functions of Mdm2 that are p53-dependent, we have generated an Mdm2 conditional mouse model. Using primary mouse embryonic fibroblasts derived from Mdm2 conditional mice, we demonstrate that p21 is required for p53-dependent apoptosis initiated by Mdm2 loss. In support of this observation, we also note that p21-loss partially rescues embryonic lethality of Mdm2 null mice. We further show that p21-loss partially rescues the embryonic lethality caused by the loss of the Mdm2 family member, Mdm4. We address the possibility that Mdm2 and Mdm4 may play redundant roles during embryonic development and find that Mdm2 overexpression fully rescues the embryonic lethality resulting from Mdm4 loss. Our findings demonstrate that both Mdm2 and Mdm4 play critical roles in modulation of the p53 tumor suppressor pathway and that their deregulation can result in tumor formation through both p53-dependent and independent pathways. Cell Division Mice, Transgenic Nuclear Proteins Tumor Suppressor Protein p53 Proto-Oncogene Proteins Tumor Suppressor Proteins Academic Dissertations Life Sciences Medicine and Health Sciences
327	Role of the Sid2-Mob1 Kinase Complex in Controlling the Onset of Cytokinesis in the Fission Yeast Schizosaccharomyces Pombe: a Dissertation Hou, Ming-Chin 15 March 2004 (has links) Cytokinesis is a fundamental step of cell proliferation by which daughter cells acquire equal amounts of genetic materials and cellular components. Cytokinesis is precisely regulated in a temporal and spatial manner to ensure that cytokinesis does not occur until chromosome segregation is complete. Failed or precocious cell division causes aneuploidy and/or polyploidy, which is often associated with cancer. In order to coordinate cytokinesis with mitosis, signaling networks have evolved in eukaryotic organisms to faithfully control late cell cycle progression by triggering cytokinesis once mitotic events have been successfully accomplished. In the fission yeast Schizosaccharomyces pombe, this conserved signaling network is known as the septation initiation network (SIN), which triggers actomyosin ring constriction and septum formation after chromosome segregation. The key output of the SIN is thought to be Sid2p kinase activity because Sid2p kinase is the most downstream component of the SIN identified so far, and in addition to the spindle pole bodies Sid2p also localizes to the division site at the end of anaphase, suggesting that Sid2p kinase transmits the division signal from the SPB to the division site, thereby triggering actomyosin ring constriction and septum formation. However, how Sid2p kinase activity is regulated during the cell cycle is still unclear. The goal of this thesis is to understand how Sid2p kinase is regulated. We identified and characterized Mob1p as a novel component of the SIN and a binding partner of the Sid2p kinase. We found that Mob1p is an essential regulatory component important for Sid2p kinase function. Furthermore, we found that phosphorylation is essential for activation of Sid2p kinase and that self-association is able to antagonize Sid2p kinase activity. Thus, we conclude that Sid2p kinase may utilize multiple modes of regulation, including Mob1p binding, stimulatory phosphorylation, and self-association, to control initiation of cytokinesis. Considering the conservation of Mob1p and Sid2p families in the eukaryotes, it is likely that other eukaryotic organisms utilize similar mechanism(s) to control cytokinesis. Cell Division Gene Expression Regulation, Fungal Phosphorylation Protein Kinases Schizosaccharomyces pombe Proteins Signal Transduction Academic Dissertations Life Sciences Medicine and Health Sciences
328	Translational Control of M Phase Progression: a dissertation Padmanabhan, Kiran 30 May 2006 (has links) A cell integrates mitogenic signals received at the plasma membrane with intracellular biochemical changes to direct the events of cell division. Oocytes from Xenopus laevis offer a system that allows molecular dissection of pathways controlling cell growth and division in response to extracellular cues. Xenopus oocytes, physiologically arrested in a G2 like state, respond to the hormone progesterone to reinitiate meiosis and mature into a fertilizable egg. Signals received at the oocyte membrane induce translation of dormant maternal mRNAs that not only drive meiotic entry but also maintain the cell cycle arrest in an egg. A major pathway controlling the translation of these mRNAs is cytoplasmic polyadenylation, facilitated by the Cytoplasmic Polyadenylation Element Binding protein (CPEB) through cis-acting elements in their 3'untranslated regions (3'UTRs). Cytoplasmic polyadenylation requires the phosphorylation of serine174 on CPEB by Aurora-A as well as the translation of a hitherto unknown mRNA. The transcript of the RINGO/Spy gene is a putative candidate for this unknown upstream regulator of CPEB function. RINGO/Spy mRNA is translationally repressed in immature oocytes by a ribonucleoprotein (RNP) complex consisting of the repressor Pumilio-2, the putative activator Deleted in Azoospermia-like (DAZl) and embryonic poly A binding protein (ePAB). Progesterone signaling leads to the dissociation of Pumilio-2 from the mRNP and the ensuing RINGO/Spy protein synthesis, in turn, promotes cytoplasmic polyadenylation and oocyte maturation. Pumilio and its associated proteins, such as Drosophila Brain tumor (Brat) and DAZl, in addition to their cytoplasmic roles have ill-defined functions within the nucleus. We detected DAZl within the nucleoli of telomerase-immortalized human retinal pigment epithelial (RPE) cells in interphase and on acrocentric chromosomes during mitosis. DAZl colocalizes with the RNA polymerase I associated Upstream Binding transcription Factor (UBF), most likely through pre-ribosomal RNA and is a likely component of the Nucleolar Organization Region (NOR). Stably knocking down DAZl in RPEs using short hairpin RNAs results in loss of nucleolar segregation, the physiological outcome of which is under investigation. These preliminary findings indicate an additional role for DAZl within the nucleolus, one likely to be independent from cytoplasmic translational control. Cell Division Xenopus Proteins 3' Untranslated Regions Cell Cycle Proteins Oocytes Polyadenylation RNA-Binding Proteins Transcription Factors Academic Dissertations Life Sciences Medicine and Health Sciences
329	Roles of the Mother Centriole Appendage Protein Cenexin in Microtubule Organization during Cell Migration and Cell Division: A Dissertation Hung, Hui-Fang 03 August 2016 (has links) Epithelial cells are necessary building blocks of the organs they line. Their apicalbasolateral polarity, characterized by an asymmetric distribution of cell components along their apical-basal axis, is a requirement for normal organ function. Although the centrosome, also known as the microtubule organizing center, is important in establishing cell polarity the mechanisms through which it achieves this remain unclear. It has been suggested that the centrosome influences cell polarity through microtubule cytoskeleton organization and endosome trafficking. In the first chapter of this thesis, I summarize the current understanding of the mechanisms regulating cell polarity and review evidence for the role of centrosomes in this process. In the second chapter, I examine the roles of the mother centriole appendages in cell polarity during cell migration and cell division. Interestingly, the subdistal appendages, but not the distal appendages, are essential in both processes, a role they achieve through organizing centrosomal microtubules. Depletion of subdistal appendages disrupts microtubule organization at the centrosome and hence, affects microtubule stability. These microtubule defects affect centrosome reorientation and spindle orientation during cell migration and division, respectively. In addition, depletion of subdistal appendages affects the localization and dynamics of apical polarity proteins in relation to microtubule stability and endosome recycling. Taken together, our results suggest the mother centriole subdistal appendages play an essential role in regulating cell polarity. A discussion of the significance of these results is included in chapter three. Heat-Shock Proteins Cell Division Cell Movement Cell Polarity Centrioles Centrosome Endosomes Epithelial Cells Microtubule-Organizing Center Microtubules Cenexin Dissertations, UMMS Cell Biology Cellular and Molecular Physiology
330	Functional Analysis of the c-MYC Transactivation Domain: A Dissertation Seth, Alpna 01 December 1992 (has links) Many polypeptide growth factors act by binding to cell surface receptors that have intrinsic tyrosine kinase activity. Binding of these growth factors to their cognate receptors results in the initiation of mitogenic signals which then get transduced to the interior of the cell. A critical target for extracellular signals is the nucleus. A plethora of recent evidence indicates that extracellular signals can affect nuclear gene expression by modulating transcription factor activity. In this study, I have determined that the transactivation domain of c-Myc (protein product of the c-myc proto-oncogene) is a direct target of mitogen-activated signaling pathways involving protein kinases. Further, my study demonstrates that transactivation of gene expression by c-Myc is regulated as a function of the cell cycle. c-Myc is a sequence-specific DNA binding protein that forms leucine zipper complexes and can act as a transcription factor. Although, significant progress has been made in understanding the cellular properties of c-Myc, the precise molecular mechanism of c-Myc function in oncogenesis and in normal cell growth is not known. I have focused my attention on the property of c-Myc to function as a sequence-specific transcription factor. In my studies, I have employed a fusion protein strategy, where the transactivation domain of the transcription factor c-Myc is fused to the DNA binding domain and nuclear localization signal of the yeast transcription factor GAL4. This fusion protein was expressed together with a plasmid consisting of specific GAL4 binding sites cloned upstream of a minimal E1b promoter and a reporter gene. The activity of the c-Myc transactivation domain was measured as reporter gene activity in cell extracts. This experimental approach enabled me to directly monitor the activity of the c-Myc transactivation domain. Results listed in Chapter II demonstrate that the transactivation domain of c-Myc at Ser-62 is a target of regulation by mitogen-stimulated signaling pathways. Furthermore, I have determined that a mitogen activated protein kinase, p41mapk, can phosphorylate the c-Myc transactivation domain at Ser-62. Phosphorylation at this site results in a marked increase in transactivation of gene expression. A point mutation at the MAP kinase phosphorylation site (Ser-62) causes a decrease in transactivation. c-Myc expression is altered in many types of cancer cells, strongly implicating c-myc as a critical gene in cell growth control. The molecular mechanisms by which c-Myc regulates cellular proliferation are not understood. For instance, it is not clear where in the cell cycle c-Myc functions and what regulates its activity. In exponentially growing cells, the expression levels of c-Myc remain unchanged as the cells progress through the cell cycle. The function of c-Myc may therefore be regulated by a mechanism involving a post-translational modification, such as phosphorylation. Results described in chapter IV demonstrate that the level of c-Myc mediated transactivation oscillates as cells progress through the cell cycle and was greatly increased during the S to G2/M transition. Furthermore, mutation of the phosphorylation site Ser-62 in the c-Myc transactivation domain diminishes this effect, suggesting a functional role for this phosphorylation site in the cell cycle-specific regulation of c-Myc activity. Taken together, my dissertation study reveals a molecular mechanism for the regulation of nuclear gene expression in response to mitogenic stimuli. Proto-Oncogene Proteins c-myc DNA-Binding Proteins Transcription Factors Cell Division Growth Substances Peptides Academic Dissertations Dissertations, UMMS Life Sciences Medicine and Health Sciences

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