Global ETD Search

221	The characterization of the cytoskeleton and associated proteins in the formation of wound-induced contractile arrays / Stromme, Adrianna. January 2008 (has links) The cytoskeleton is an intrinsic aspect of all cells, and is essential for many cellular events including cell motility, endocytosis, cell division and wound healing. Remodeling of the cytoskeleton in response to these cellular activities leads to significant alterations in the morphology of the cell. One such alteration is the formation of an actomyosin contractile array required for cytokinesis, wound healing and embryonic development. / Cellular structure and shape depends upon tensional prestress brought about by the organization of cytoskeletal components. Using the Xenopus laevis oocyte wound healing model, it is first described how diminished cellular tension affects the balance of the Rho family of GTPases, and subsequently prevents the formation of actomyosin contractile arrays. This suggests that cellular tension in the cell is not created at the level of the cytoskeletal elements but rather via the upstream signaling molecules: RhoA and Cdc42. / The role of N-WASP (Neural-Wiscott Aldrich Syndrome Protein), a mediator of Arp2/3 based actin polymerization, is next examined for its putative role in cellular wound healing. Xenopus laevis oocytes injected with mutant N-WASP constructs reveals in vivo evidence that functional N-WASP is required for appropriate contractile array formation and wound closure. / Lastly, it is revealed that the cellular structures involved with single cell wound healing in other model systems are also important for the initial repair of severed muscle cells. Actin, non-muscle myosin-II, microtubules, sarcomeric myosin and Cdc42 are all recruited and reorganized at the edge of damaged C2C12 myotubes. This data promotes the possibility that an actomyosin array may be established in injured muscle cells as well. Actomyosin -- physiology. Contractile Proteins -- physiology. Wound Healing -- physiology. cdc42 GTP-Binding Protein -- metabolism. rhoA GTP-Binding Protein -- metabolism. Oocytes -- physiology. Xenopus laevis.
222	Régulation transcriptionelle du développement de l'hypothalamus chez l'amphibien Bouyakdan, Khalil 08 1900 (has links) Le noyau paraventriculaire (PVN) de l'hypothalamus régule une série de phénomènes physiologiques incluant l'équilibre énergétique et la pression artérielle. Nous avons identifié une cascade de facteurs de transcription qui contrôle le développement du PVN. SIM1 et OTP agissent en parallèle pour contrôler la différenciation d'au moins cinq types de neurones identifiables par la production d'OT, AVP, CRH, SS et TRH. Ces Facteurs de transcriptions contrôlent le développement des lignées CRH, AVP et OT en maintenant l'expression de Brn2 qui à son tour est nécessaire pour la différenciation terminale de ces neurones. L'analyse du transcriptome du PVN nous a permis d'identifier plusieurs gènes qui ont le potentiel de contrôler le développement du PVN. Nous voulons développer un paradigme de perte de fonction qui permettrait l'étude de ces gènes candidats sur une grande échelle. Le but de ce projet est de caractériser le PVN en développement de l'amphibien en vue de l'utilisation de ce modèle pour des études fonctionnelles. Nous avons cloné des fragments de cDNA de Sim1, OTP, Brn2, Sim2, CRH, Ot, AVP et TRH à partir de l'ARN total de Xenopus Laevis. Nous avons adapté notre technique d'hybridation in situ pour caractériser l'expression de ces gènes chez l'amphibien aux stades 33-39, 44, 51, 54, 60, et chez l'adulte. Résultats. Les Facteurs de transcription Sim1, OTP, et Brn2 commencent à être exprimés dans le PVN prospectif au stade 33. L'expression des marqueurs de différenciation terminale devient détectable entre les stades 37 et 39. De façon intéressante, le PVN occupe initialement un domaine de forme globulaire puis à partir du stade 44 s'allonge le long de l’axe dorso-ventral. Cet allongement se traduit par une organisation en colonnes des cellules du PVN que nous n'avons pas observée chez les rongeurs. Le développement du PVN est conservé chez l'amphibien dans la mesure où la relation entre l'expression des facteurs de transcription et des marqueurs de différenciation terminale est conservée. Il existe par ailleurs des différences entre la topographie des PVN des mammifères et de l'amphibien. L'organisation en colonnes de cellules pourrait correspondre à des mouvements de migration tangentielle. Nous sommes maintenant en mesure de tester la fonction des facteurs de transcription dans le PVN par l'approche d'invalidation par morpholinos. / The paraventricular nucleus PVN of the hypothalamus regulates a series of physiological phenomena including the maintenance of energetic balance and arterial blood pressure. We have previously identified a cascade of transcription factors that control the development of the PVN. Sim1 and OTP act in concert to mediate the terminal differentiation of at least five types of neurons identifiable by their production of OT, AVP, CRH, SS and TRH. These transcription factors control the development of the OT, AVP and CRH producing neurons by maintaining the expression of Brn2, which is in turn required for the terminal differentiation of these cell lines. The transcriptome analysis of the PVN allowed us to identify a handful of genes that are potentially implicated in the development of this brain structure. Our goal is to develop a loss of function paradigm that would allow a high troughput study of these candidate genes. The main goal of this project is to characterize the developing PVN in the amphibian in order to use this model in our functional studies of these genes. We have cloned fragments of cDNA of Sim1, OTP, Brn2, Sim2, CRH, TRH, AVP and OT using Xenopus laevis total RNA. We have also adapted our in situ hybridization technique to characterize the expression of these genes in stage 33-39, 44, 51, 54, 60 and adult amphibian brain. Sim1, OTP and Brn2 are expressed in the prospective PVN as soon as stage 33. The expression of the terminal differentiation markers become detectable between stages 37-39. Interestingly, the PVN is initially restricted to a more globular domain and begins to extend along the dorso-ventral axis at around stage 44. This vertical extension translates into a column organization that we do not observe in rodents. The development of the PVN is well conserved in the amphibian in the sense that the relation between the expression of the different transcription factors and the terminal differentiation markers is conserved. We can also observe some topographical differences between the mammalian and amphibian PVN. The column organization the different PVN cell types might correspond to the tangential migration that is observed in the mouse. We are now well equipped to test the function in the PVN of the known transcripton factors as well as the candidate genes previously identified in our lab using a morpholino-mediated gene knock down. Xenopus laevis Hypothalamus Noyau paraventriculaire Facteur de transcription Différentiacion terminale Trh Crh Avp Sim1 Otp Brn2 Transcription factors Terminal differentiation
223	Bt maize and frogs : an investigation into possible adverse effects of Bt toxin exposure to amphibian larvae / J.L. Zaayman. Zaayman, Jazel Larissa January 2012 (has links) Genetically modified maize expressing the Bt-protein Cry1Ab (Bt maize) is planted widely in South Africa. Crop residues of Bt maize often end up in aquatic ecosystems where aquatic organisms are exposed to Cry1Ab protein. The effect of this protein on non-target aquatic organisms has not yet been studied in South Africa. The aim of this study was to evaluate the possible effect of exposure to Bt maize on morphological development of Xenopus laevis and Amietophrynus gutturalis tadpoles. Three experiments were conducted with each of X. laevis and A. gutturalis. Five of these were conducted in the bio-secure Amphibian Biology laboratory and one with A. gutturalis in a shade-house facility where microcosms were exposed to natural conditions. In the first experiment of X. laevis and A. gutturalis, which was replicated three times, large portions of maize leaves were placed in the bottoms of microcosms. X. laevis received supplementary pulverised leaves in suspension while A. gutturalis tadpoles fed on provided leaves. For both control and experimental groups microcosms were divided in three groups receiving respectively 15, 30 and 45 g of maize leaves. In the second and third experiment tadpoles only received pulverised Bt maize leaves in suspension. Each replicate (microcosm) contained 50 one-day old tadpoles. Experiment two was conducted to determine whether the Bt-protein has adverse effects on A. gutturalis tadpoles when tadpoles are exposed to the protein in the water but not feeding on the plant material. A total of 100 tadpoles were used during the experiment and tadpoles were placed individually in 250 ml plastic cups that were filled with 100 ml water witch contained an extract of either Bt and non-Bt maize leaves. Tadpoles were fed twice a week with TetraTabimin bottom-feeding fish pellets in suspension. Experiment three was conducted to determine whether the Bt-protein will have adverse effects on A. gutturalis tadpoles when tadpoles feed on Bt maize leaves. Tadpoles were divided into a treatment in which 50 tadpoles were fed Bt maize leaves and a control treatment in which 50 tadpoles were fed non-Bt maize leaves. Tadpoles were placed individually in 250 ml plastic cups that were each filled with 100 ml borehole water. On a weekly basis 10 randomly selected tadpoles were collected, measured and staged for morphological development, using the Nieuwkoop and Faber Normal Table for X. laevis and Gosner stages for A. gutturalis tadpoles. The significant effects observed in some life history parameters of tadpoles exposed to Cry1Ab protein cannot be ascribed to the effect of the protein. Poor husbandry turned out to be the single most important confounding factor. Before follow-up studies are conducted husbandry practices should be optimized. / Thesis (MSc (Environmental Sciences))--North-West University, Potchefstroom Campus, 2013. Bt maize Bt-protein Cry1Ab Xenopus laevis Amietophrynus gutturalis Nieuwkoop and Faber Normal Table Gosner staging Bt-mielies Bt-protiën Nieuwkoop en Faber Normale Tabel Gosner stadiums
224	Bt maize and frogs : an investigation into possible adverse effects of Bt toxin exposure to amphibian larvae / J.L. Zaayman. Zaayman, Jazel Larissa January 2012 (has links) Genetically modified maize expressing the Bt-protein Cry1Ab (Bt maize) is planted widely in South Africa. Crop residues of Bt maize often end up in aquatic ecosystems where aquatic organisms are exposed to Cry1Ab protein. The effect of this protein on non-target aquatic organisms has not yet been studied in South Africa. The aim of this study was to evaluate the possible effect of exposure to Bt maize on morphological development of Xenopus laevis and Amietophrynus gutturalis tadpoles. Three experiments were conducted with each of X. laevis and A. gutturalis. Five of these were conducted in the bio-secure Amphibian Biology laboratory and one with A. gutturalis in a shade-house facility where microcosms were exposed to natural conditions. In the first experiment of X. laevis and A. gutturalis, which was replicated three times, large portions of maize leaves were placed in the bottoms of microcosms. X. laevis received supplementary pulverised leaves in suspension while A. gutturalis tadpoles fed on provided leaves. For both control and experimental groups microcosms were divided in three groups receiving respectively 15, 30 and 45 g of maize leaves. In the second and third experiment tadpoles only received pulverised Bt maize leaves in suspension. Each replicate (microcosm) contained 50 one-day old tadpoles. Experiment two was conducted to determine whether the Bt-protein has adverse effects on A. gutturalis tadpoles when tadpoles are exposed to the protein in the water but not feeding on the plant material. A total of 100 tadpoles were used during the experiment and tadpoles were placed individually in 250 ml plastic cups that were filled with 100 ml water witch contained an extract of either Bt and non-Bt maize leaves. Tadpoles were fed twice a week with TetraTabimin bottom-feeding fish pellets in suspension. Experiment three was conducted to determine whether the Bt-protein will have adverse effects on A. gutturalis tadpoles when tadpoles feed on Bt maize leaves. Tadpoles were divided into a treatment in which 50 tadpoles were fed Bt maize leaves and a control treatment in which 50 tadpoles were fed non-Bt maize leaves. Tadpoles were placed individually in 250 ml plastic cups that were each filled with 100 ml borehole water. On a weekly basis 10 randomly selected tadpoles were collected, measured and staged for morphological development, using the Nieuwkoop and Faber Normal Table for X. laevis and Gosner stages for A. gutturalis tadpoles. The significant effects observed in some life history parameters of tadpoles exposed to Cry1Ab protein cannot be ascribed to the effect of the protein. Poor husbandry turned out to be the single most important confounding factor. Before follow-up studies are conducted husbandry practices should be optimized. / Thesis (MSc (Environmental Sciences))--North-West University, Potchefstroom Campus, 2013. Bt maize Bt-protein Cry1Ab Xenopus laevis Amietophrynus gutturalis Nieuwkoop and Faber Normal Table Gosner staging Bt-mielies Bt-protiën Nieuwkoop en Faber Normale Tabel Gosner stadiums
225	Aurora A kinase function during anaphase Lioutas, Antonio, 1980- 09 November 2012 (has links) Aurora A (AurA) is an important mitotic kinase mainly studied for its involvement in cell cycle progression, centrosome maturation, mitotic spindle pole organization and bipolar spindle formation. It localizes to duplicated centrosomes and spindle microtubules (MTs) during mitosis where it regulates various factors participating in metaphase spindle formation. AurA is degraded late in mitosis suggesting that it might also have a function in anaphase. In this study we focused in understanding AurA function during anaphase in two different experimental systems. First, we kept AurA active in cycled Xenopus egg extracts and found that MTs maintained their mitotic organization longer throughout mitotic exit. We also observed chromosome segregation defects and problematic nuclear envelope formation. These observations indicate that AurA activity needs to be down-regulated for the transition from metaphase back to interphase. To get insights into the role of AurA during metaphase-anaphase transition we initially asked whether its kinase activity is still necessary for the maintenance of the metaphase spindle. We saw that the inhibition of AurA kinase activity in metaphase resulted to a collapse of the established metaphase spindle in HeLa cells. Indicating that AurA activity is necessary for the metaphase spindle maintenance. Then, we looked whether AurA kinase activity is still necessary during anaphase. We inhibited AurA at the onset of anaphase in Hela cells and found that anaphase spindles were smaller. We also observed that the MT structure responsible for anaphase spindle elongation, the central spindle, was defectively assembled and organized. Moreover, in cells where AurA was inhibited segregation of chromosomes was defective. These results indicate that AurA kinase activity is necessary for anaphase spindle elongation, central spindle assembly and organization and chromosome segregation. To understand further how AurA regulates anaphase spindle formation we looked known AurA substrates. We depleted TACC3, a known AurA substrate involved in MT formation earlier in mitosis and observed that TACC3 depletion phenocopied AurA inhibition. This indicates that TACC3 has a function in MT organization and chromosome segregation during anaphase and this function could possibly be regulated by AurA. In this study we have demonstrated that AurA activity is essential for metaphase spindle maintenance. We also found that during anaphase when AurA is either maintained active or inhibited MT organization is greatly affected and chromosome segregation is defective. Suggesting that AurA activity needs to be tightly controlled during anaphase for a correct completion of mitosis. / Aurora A (AurA) es una quinasa mitótica importante que se ha estudiado principalmente en su papel durante la progresión del ciclo celular, la maduración del centrosoma, la organización y la formación del polo y del huso mitótico. Durante la mitosis, AurA se localiza en los centrosomas duplicados y en los microtúbulos (MTs) del huso y se ha observado que regula varios factores que participan en la formación del huso mitótico. AurA se degrada al final de la mitosis indicando que pueda tener una función durante la anafase. En este estudio nos hemos centrado en la comprensión de la función de AurA durante la anafase en dos sistemas experimentales diferentes. En primer lugar, utilizando extractos de huevos de Xenopus hemos mantenido AurA activa durante la transición de metafase a anafase y hemos visto que los MTs del huso mitótico mantienen su organización durante más tiempo. También hemos observado que cuando AurA se mantiene activa existen defectos en la segregación cromosómica y la formación de la membrana nuclear. Esto indica que la actividad de AurA tiene un papel regulador sobre los MTs y la chromatina durante la transición de la metafase a la interfase. Para entender cual es la función de AurA durante la transición de metafase a anafase primero hemos estudiado si la actividad de la quinasa es necesaria para el mantenimiento del huso mitótico. Hemos visto que la inhibición de la actividad quinasa AurA resultó en el colapso del huso durante la metafase en células HeLa. Esto indica que la actividad de AurA es necesaria para el mantenimiento del huso mitótico de metafase. A continuación hemos analizamos si la actividad quinasa de AurA sigue siendo necesaria para la anafase. Para ello hemos inhibido AurA en células Hela al inicio de la anafase. En estas condiciones los husos de la anafase son más pequeños y la estructura de los MTs responsable del alargamiento del huso mitótico durante la anafase, el huso central, se organiza defectuosamente. Además, se encontraron errores durante la segregación de los cromosomas. Estos resultados indican que la actividad quinasa de AurA es necesaria para el alargamiento del huso durante la anafase y la organización y segregación cromosómica. Para entender el mecanismo de la función de AurA durante la anafase hemos estudiado a sustratos de AurA. Al estudiar TACC3 , un sustrato conocido de AurA que participa en la formación de MTs en las fase iniciales de la mitosis hemos encontrado que su eliminación de células HeLa produce el mismo fenotipo que la inhibición de AurA. Esto indica que TACC3 tiene una función en la organización de MT y la segregación de cromosomas durante la anafase y que esta función podría estar regulada por la quinasa AurA. En este estudio hemos demostrado que la actividad quinasa de AurA es esencial para el mantenimiento del huso mitótico. También hemos encontrado que durante la anafase cuando la quinasa AurA se mantiene activa o se inhibe la organización de los MTs del huso mitótico se ve muy afectada y los cromosomas se segregan defectuosamente. Por tanto los resultados de este estudio indican que la actividad quinasa de AurA está estrechamente controlada durante la anafase para el correcto cumplimiento de la mitosis. Fus mitòtic Xenopus laevis Embriologia Centrosomes Mitosi HeLa cells Xenopus egg extract Cell cycle Mitotis Mitotic spindle Centrosome Kinase Anaphase Central spindle Microtubules Aurora A TPX2 TACC3 Augmin 576
226	Etude de la fonction de la protéine de liaison à l'ARN XSEB4R dans la formation de l'ectoderme chez le xénope Bentaya, Souhila 30 May 2013 (has links) Une étape initiale fondamentale dans le développement des vertébrés est l'organisation des cellules de l'embryon en trois feuillets embryonnaires primordiaux: ectoderme, mésoderme et endoderme. Chez l'embryon de xénope, le développement de l'endoderme et l’induction du mésoderme est initié par le gène maternel VegT codant pour un facteur de transcription à boîte T dont l'ARNm est localisé au pôle végétatif de l'ovocyte. Actuellement, les facteurs et mécanismes impliqués dans la formation de l'ectoderme, qui reste pluripotent jusqu'à la gastrulation, sont mal connus.<p>Des travaux récents du laboratoire ont montré que le gène XSeb4R, codant pour une protéine de liaison à l'ARN à motif RRM, présente maternellement de manière ubiquitaire dans la blastula, interagit directement avec la région 3'UTR de l'ARNm VegT, stabilisant et stimulant sa traduction. La déplétion de XSEB4R inhibe la formation de l'endoderme et du mésoderme et sa surproduction produit l’effet inverse. Ces observations ont montré que XSeb4R joue un rôle essentiel via VegT dans la formation de l'endoderme et du mésoderme. <p>Dans cette étude, nous avons testé l’hypothèse selon laquelle XSeb4R jouerait également un rôle au pôle animal dans la spécification de l’ectoderme. Nos résultats montrent que la protéine XSEB4R lie les régions 3’UTR des transcrits Sox3, Zic2a et Zic2b. Nous avons observé que la surexpression de XSeb4R stabilise les transcrits maternels Sox3 et Zic2 a et b, et qu’elle active la traduction des transcrits Zic2b mais pas celle de Sox3 ou Zic2a. Enfin, nous avons montré que la perte de fonction de XSeb4R induit une expansion du mésoderme vers l’ectoderme dans l’embryon au stade blastula. Ces résultats démontrent que XSeb4R joue un rôle important dans la spécification de l’ectoderme chez l’embryon de xénope.<p> / Doctorat en Sciences / info:eu-repo/semantics/nonPublished Biologie Sciences exactes et naturelles Developmental biology Germinal layers Xenopus laevis -- Embryology Biologie du développement Feuillets embryonnaires Dactylèthre du Cap -- Embryologie XSeb4R Sox3 Ectoderme Zic2
227	Etude du facteur de transcription XHRT1 dans le développement embryonnaire chez le xénope Taelman, Vincent 04 November 2005 (has links) Le laboratoire d’Embryologie Moléculaire étudie les mécanismes moléculaires contrôlant le développement embryonnaire et utilise comme système expérimental l’embryon de xénope. En collaboration le laboratoire du Dr Daniel Christophe, nous avons abordé l’étude du gène XHRT1 chez le xénope. Ce gène est l’orthologue du gène HRT-1/Hey1/Hesr-1/HERP2/CHF2 de souris. Celui-ci, avec deux autres protéines apparentées (HRT2 et HRT3) forme une sous-famille de facteurs de transcription de type bHLH-O qui se différencient des autres facteurs bHLH-O par l’absence d’un motif carboxy-terminal de séquence « WRPW » et par la présence d’un nouveau motif carboxy-terminal conservé de séquence « TEI/VGAF ». Le rôle de ces facteurs HRT dans le développement est encore actuellement mal connu. <p>Dans un premier temps, nous avons déterminé le profil d’expression de XHRT1 au cours de l’embryogenèse. Nous avons observé que ce gène est fortement exprimé au stade neurula dans le plancher du tube neural, et que plus tardivement celui-ci est exprimé dans différentes régions du système nerveux, dans les somites et le dans le pronéphros. Comme attendu pour un membre de la famille des facteurs bHLH-O, nous avons également observé que l’expression précoce de HRT1 au niveau du plancher du tube neural est bien régulée par la voie de signalisation Notch.<p>Dans un deuxième temps, nous nous sommes intéressés au rôle et au mode d’action du facteur XHRT1 dans le développement du plancher du tube neural. Nous avons pu montrer que XHRT1 agit comme répresseur transcriptionnel et que cette répression nécessite la présence du domaine bHLH et de séquences en aval de celui-ci. Nous avons montré en embryon que la surexpression précoce de XHRT1 induit un blocage de l’expression des marqueurs du mésoderme et une augmentation de marqueur du plancher du tube neural, ce qui est en accord avec le modèle selon lequel la voie de signalisation Notch interviendrait dans le choix de la destinée des cellules de la région médiane en inhibant la différenciation des cellules en notocorde et en favorisant leur différenciation en cellules du plancher du tube neural. XHRT1 n’étant cependant activé qu’à partir du stade neurula, nous avons conclu que les effets observés n’étaient probablement pas dus à XHRT1 mais à un autre facteur bHLH-O apparenté exprimé plus précocement dans les cellules de la ligne mediane de l’embryon. Afin d’éviter ces effets non spécifiques précoces, nous avons utilisé un vecteur d’expression de XHRT1 permettant un contrôle temporel de l’activité de la protéine. Nous avons ainsi montré que l’activation de XHRT1 au stade neurula dans l’ectoderme inhibe la différenciation des cellules précurseurs neurales en neurones et qu’il pourrait ainsi jouer un rôle important dans le développement du plancher du tube neural. Nos résultats ont montré également que XHRT1 est capable d’homo- et hétérodimériser in vivo avec les facteurs Xhairy1 et Xhairy2b coexprimés avec XHRT1 dans le plancher du tube neural. Enfin, nous avons montré que les propriétés de dimérisation de XHRT1 sont dépendantes non seulement du domaine bHLH, mais aussi du domaine Orange et des séquences situées en aval, séquences jouant un rôle important dans le choix du partenaire.<p>Des travaux récents ayant montré que la voie de signalisation Notch joue un rôle important dans le développement du rein, nous avons voulu déterminer l’importance de XHRT1 dans le développement du pronéphros. Nos résultats ont montré que XHRT1 ainsi que d’autres facteurs bHLH-O sont exprimés de manière dynamique, d’abord dans le glomus puis dans la partie dorso-antérieure de l’ébauche du pronéphros à l’origine des tubules proximaux, et que leur expression est régulée positivement par Notch. La surexpression de XHRT1 à la fin de la neurulation inhibe la formation du canal et du tubule distal, tandis que l’inhibition de la traduction de la protéine entraîne une réduction de l’expression de marqueurs spécifiques des tubules proximaux et du glomus. Ces résultats démontrent que XHRT1 joue un rôle important comme médiateur de la voie de signalisation Notch dans le pronéphros. / Doctorat en sciences, Spécialisation biologie moléculaire / info:eu-repo/semantics/nonPublished Sciences exactes et naturelles Biologie Developmental neurobiology Embryology Neurologie du développement Embryologie pronephros Notch signalling XHRT1 HRT1 bHLH Hey1 bHLH-O neural plate floor plate Orange domain xenopus laevis
228	Survival of the Retinal Pigment Epithelium in Vitro: Comparison of Freshly Isolated and Subcultured Cells Uebersax, Eva D., Grindstaff, Rachel D., Defoe, Dennis M. 01 January 2000 (has links) Cells of the retinal pigment epithelium (RPE) are generated prenatally and generally survive the lifetime of the individual without undergoing proliferation or replacement. Therefore, the mechanisms promoting individual RPE cell survival and longevity in vivo may be distinct from, or a limited subset of, the mechanisms known to promote survival in proliferative cells in culture. To identify specific factors that sustain cell viability independent of effects on cell division, we studied RPE cells in low-density suspension culture, in which cell proliferation is inhibited. Single cells from Xenopus laevis eyes were plated onto a non-adhesive surface in protein-free medium, then assayed for survival using the 3-(4, 5-dimethylthiazol-2-yl)-2,5-diphenyl tetrazolium bromide (MTT) assay. Cell viability in these cultures was essentially undiminished over the initial 2 days. However, by approximately 1 week in culture, only an average of 53% of the cells remained alive. Plating cells on a fibronectin-coated substratum significantly enhanced survival, such that the number of cells alive at 1 week was 80-90% of the initial level. Essentially identical results were obtained with laminin- or collagen IV-coated substrata, or with insulin (5μg ml-1) in the medium. The absence of cell division in these cultures was confirmed by cell counting and BrdU incorporation experiments. Interestingly, in suspension cultures derived from monolayers previously established on microporous membrane filters, cells lost viability much faster (average of 80% dead at 3 days), and showed a relatively greater response to extracellular matrix proteins (five-fold increase in cell survival at 3 days). Enhanced RPE survival in response to fibronectin required spreading of the cell on a substratum, rather than mere adherence, as there was a high correlation between the percentage of spread cells and the percentage that were MTT-positive (r = 0·940). Cell spreading apparently enhanced survival by preventing the initiation of programmed cell death: unattached non-viable cells in culture exhibited morphological features expected of apoptosis, as well as positive staining by the TUNEL reaction. These studies demonstrate that, of several factors shown to maintain or increase cell number in proliferating cultures, some have their effect, at least in part, by promoting the survival of individual cells. The increased susceptibility of subcultured RPE to cell death has implications for clinical transplantation applications that may require manipulation of RPE in vitro. apoptosis cell adhesion cell survival EGF extracellular matrix fibronectin insulin MTT poly(HEMA) programmed cell death RPE suspension culture TUNEL assay Xenopus laevis Biomedical Sciences
229	Signaling Events Leading to CPEB-Mediated Translation: a Dissertation Sarkissian, Madathia 12 July 2004 (has links) Fully grown oocytes' of the African clawed frog, Xenopus laevis, are arrested at the diplotene stage of meiotic prophase I, which resembles the G2 phase of the mitotic cell cycle. Re-entry into the meiotic divisions is initiated by hormonal signaling normally provided by progesterone. Progesterone signaling leads to the activation of maturation promoting factor (MPF), a heterodimer consisting of the protein kinase cdk1 and cyclin B1; this complex promotes the oocyte's entry into M phase of meiosis I. A crucial event required for MPF activation is cytoplasmic polyadenylation element (CPE)-mediated translation of specific dormant mRNAs such as c-mos and cyclin B1. The CPE, which resides in mRNA 3' untranslated region (UTR), is bound by the CPE binding protein (CPEB), which in turn is bound by Maskin. Maskin is bound to the 5' cap binding protein eIF4E. This type of closed-loop mRNA structure inhibits the recruitment and assembly of the translation initiation complex at the 5'UTR of CPE containing mRNAs. To alleviate this inhibition, CPEB undergoes phosphorylation on S174 by the serine/threonine kinase Aurora A. Phosphorylated CPEB promotes the recruitment of specific polyadenylation factors leading to the polyadenylation of the dormant mRNA, resulting in the disassociation of Maskin from eIF4E. eIF4E is subsequently bound by translation initiation factors leading to mRNA assembly into polysomes and synthesis of the encoded protein. Insulin signaling has also been shown to induce oocyte maturation. However, this signaling cascade uniquely requires the activation of two upstream components, PI3 kinase and PKC zeta. In this thesis, I show that insulin induced oocyte maturation requires the same CPE-mediated mRNA translation mechanism as had been described for progesterone signaling. I also show that Aurora A kinase activation and S174 phosphorylation play an essential role in insulin-induced CPE-mediated mRNA translation. Interestingly, inhibition of PI3 kinase and PKC zeta inhibits CPE-mediated polyadenylation only in the insulin-signaling pathway; the progesterone pathway is unaffected. These results clearly indicate that different upstream signaling components control CPE-mediated translation between progesterone and insulin signaling cascades. However, both pathways are antagonized by over expressed GSK-3, leading to inhibition of oocyte maturation. Furthermore, I found that GSK-3 inhibits Aurora A kinase activity by directly phosphorylating Aurora A on serine 290/291, promoting an inhibitory autophosphorylation event on serine 349. The importance of a GSK-3/Aurora A interaction is underscored by the finding that GSK-3, Axin, and Aurora A reside in a complex in immature oocytes. During progesterone or insulin signaling, GSK-3 dissociates from Aurora A allowing Aurora A to become active, leading to CPEB phosphorylation, CPE-mediated mRNA translation and oocyte maturation. Insulin Oocytes Progesterone Protein Kinases Signal Transduction Transcription Factors Protein Biosynthesis Xenopus laevis Xenopus Proteins Academic Dissertations Life Sciences Medicine and Health Sciences
230	The characterization of the cytoskeleton and associated proteins in the formation of wound-induced contractile arrays / Stromme, Adrianna. January 2008 (has links) No description available. rhoA GTP-Binding Protein -- metabolism. cdc42 GTP-Binding Protein -- metabolism. Oocytes -- physiology. Wound Healing -- physiology. Xenopus laevis. Contractile Proteins -- physiology. Actomyosin -- physiology.

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