Global ETD Search

1	α1-antitrypsin mutations : an investigation of their effects on protein processing and secretion Oakley, Diana January 2000 (has links) No description available. 572.8 Deficiency; Xenopus oocytes
2	The Structural Basis for Ligand Recognition by Mouse Odorant Receptors Repicky, Sarah Elizabeth 22 April 2008 (has links) Mammalian odorant receptors (ORs) are Class I G-protein coupled receptors (GPCRs) located within the nasal epithelium. Odorant receptors interact with Galpha olfactory, a Galpha S type G-protein. Activated Galpha olfactory stimulates adenylate cyclase and the resulting increase in cAMP concentration opens cyclic nucleotide gated channels allowing Ca2+ to enter the cell. The increased Ca2+ then activates a Ca2+ activated Cl- channel which further depolarizes the cell. This depolarization initiates an action potential that reaches the axon of the olfactory sensory neuron located in the main olfactory bulb. Information from the main olfactory bulb is then transmitted to higher regions of the brain. Olfactory information is initially coded through the interaction of odorant molecules with hundreds of distinct ORs, but difficulty in exogenous expression of odorant receptors has delayed the identification of ligands for individual ORs. However, expression of mouse odorant receptors in Xenopus laevis oocytes allows for a systematic screening for potential ligands, as well as for efficient study of the structure-function relationship of the receptors and their ligands. My screening of odorant receptors using Xenopus oocytes included the coexpression of a signal transduction system and the use of robotic two-electrode voltage clamp electrophysiology. In this study, I investigated the structural basis for ligand recognition in mouse odorant receptors. First, I expanded the molecular receptor ranges of seven Class I odorant receptors. By use of a high throughput assay, I was able to expand upon current knowledge in the field for the mouse odorant receptors 23-1, 31-4, 32-11, 40-4, 42-1, 42-2 and 42-3. I then examined one receptor (MOR23-1) in more detail. I used the substituted cysteine accessibility method to identify residues within transmembrane domain five of this receptor that are accessible from the extracellular space. These residues may line the ligand binding site or the ligand access pathway. Conventional mutations of A205 caused little alteration in the molecular receptive range of the receptor, suggesting that this residue may not play a significant role in ligand interaction within the binding pocket. Mutagenesis of G111, a residue within transmembrane domain three caused significant shifts in the molecular receptive range of the receptor, but the location of this residue within the binding pocket could not be confirmed by the substituted cysteine method. Previous reports had suggested significant similarity between the molecular receptive ranges of the seven mouse odorant receptors that I used in my research. By expanding upon the known aliphatic ligands for each receptor identified new ligands for each receptor, I was able to show that the molecular receptive ranges of these receptors are in fact distinct. The experimental identification of residues located within the binding pocket on transmembrane five of mouse odorant receptor 23-1 provides an improved understanding of ligand recognition by this receptor class and will aid in better computer modeling of these receptors. This increased accuracy of the computer models of these basic Class I GPCRs may aid in future drug discoveries. Since GPCRs constitute a significant fraction of current drug targets, understanding the mechanism of ligand interactions with mouse odorant receptors may aid in the development of more efficacious compounds in the treatment of many common ailments.
3	Leukocyte P(2) purinergic receptors: Expression and characterization in Xenopus oocytes Nuttle, Louise Cathell January 1994 (has links) No description available. Biology, Animal Physiology
4	Arpp19 et Cdc6, deux régulateurs majeurs des divisions méiotiques de l'ovocyte de Xénope / Arpp19 and Cdc6, two major regulators of the meiotic division in the Xenopus oocyte Daldello, Enrico Maria 12 June 2015 (has links) L’objectif de cette thèse a été de comprendre deux caractéristiques majeures des divisions méiotiques chez la femelle: le blocage en prophase de 1ère division méiotique qui permet à l’ovocyte d’accumuler des réserves énergétiques et des déterminants nécessaires au développement embryonnaire ; et l’absence de phase-S entre les deux divisions méiotiques ce qui permet de former des cellules haploïdes aptes à la fécondation. Pour cela, j’ai choisi comme modèle d’étude l’ovocyte de Xénope qui permet de suivre ces processus in vitro en réponse à la progestérone. L’ovocyte subit les deux divisions méiotiques grâce à l’activation du facteur universel de la division cellulaire, le MPF, et se bloque en métaphase de 2ème division méiotique dans l’attente d’être fécondé. Chez tous les vertébrés, le 1er arrêt en prophase dépend de l’activité de la protéine kinase dépendante de l’AMPc, PKA, dont l’inactivation est nécessaire pour la reprise de la méiose. Le substrat de PKA dans l’ovocyte était resté inconnu. Nous avons découvert que la protéine Arpp19, jusqu’alors connue pour son rôle positif dans l’activation du MPF, est phosphorylée par PKA de cette phosphorylation bloque l’activation du MPF nécessaire pour la levée du blocage en prophase. ARPP19 possède donc un double rôle, le 1er exercé comme substrat de PKA et responsable de l’arrêt en prophase, le second dans l’activation du MPF suite à un changement dans sa phosphorylation. Dans un second temps, nous avons étudié la protéine Cdc6, un acteur majeur de la réplication de l’ADN. Absente en prophase, Cdc6 s’accumule entre les deux divisions méiotiques ce qui permet à l’ovocyte d’acquérir la compétence à répliquer l’ADN. Cette compétence ne s’exprime pas ce qui permet de réduire de moitié la ploïdie. Nous avons montré que Cdc6 est un inhibiteur puissant du MPF capable de bloquer les divisions méiotiques et d’induire la réplication de l’ADN. Pour éviter ces effets délétères l’accumulation de Cdc6 est strictement régulée lors des deux divisions méiotiques, ce qui est absolument requis pour assurer l’enchainement des deux divisions cellulaires sans phase-S intercalaire. / The goal of my PhD project was to understand two main features of the female meiotic division: the arrest in prophase of the 1st meiotic division that allows the accumulation of nutrients and determinants necessary for the embryonic cell cycles; and the absence of S-phase between the two meiotic divisions in order to produce haploid gametes. For this purpose, I studied Xenopus oocytes, a powerful model system that allows the biochemical analysis of these two processes in vitro. In ovary, oocytes are arrested in prophase I and resume meiosis in response to progesterone. The oocytes then proceed through the 1st and the 2nd meiotic divisions and halt at metaphase II, awaiting for fertilization. These two consecutive divisions are controlled by two waves of Cdk1 activation, the universal factor responsible for the entry into mitosis. I analysed the mechanisms responsible for arresting the oocyte in prophase I. In all vertebrates, this arrest depends on a high activity of the cAMP-dependent protein kinase, PKA, whose downregulation is required for the release of the prophase block. The substrate of PKA had never been identified up to date. I discovered that the small protein Arpp19, already known for positively regulating entry into M-phase, is phosphorylated by PKA in prophase I and is dephosphorylated upon progesterone addition, an event required for Cdk1 activation. Hence, Arpp19 has a dual function, responsible of the prophase arrest as a PKA substrate, and then converted into an activator of Cdk1 by changes of its phosphorylation pattern. The second part of my thesis has been dedicated to understanding the role and the regulation of the Cdc6 protein during meiotic divisions. This protein is essential for DNA replication in somatic cells. It is accumulated between the two oocyte meiotic divisions and restores the competence to replicate DNA in oocyte. However, this competence is repressed before fertilization, allowing formation of haploid cells. I found that the accumulation of Cdc6 is tightly controlled during meiotic maturation by the Cyclin B accumulation and the Mos/MAPK pathway. I further demonstrated that Cdc6 is a strong inhibitor of Cdk1 in Xenopus oocytes and that the timely accumulation of Cdc6 is required to coordinate the two meiotic divisions with no intercaling S-phase. Méiose Xenopus ovocytes Cdc6 Arpp19 Blocage en prophase Réplication de l'adn Xenopus oocytes Meiosis 571.8
5	Differential Expression and Functional Characterization of Alpha3 Beta2 Neuronal Nicotinic Acetylcholine Receptors Mizukawa, John Hideo 17 July 2008 (has links) (PDF) Neuronal nicotinic acetylcholine receptors (nAChRs) are expressed in both the periperhal and central nervous systems, and are involved in pre-, post-, and non-synaptic control of neuronal activation. In the brain, these receptors play an important role in a variety of physiological processes such as cognition, development, learning, and memory formation. Malfunction of these receptors have been implicated in neurodegenerative diseases like Alzheimer's disease (AD), schizophrenia, and Parkinson's disease. To date, 17 different nAChR subunits, including α2-α7 and β2-β4, have been cloned that can form homo- and/or hetero-pentameric ionotropic receptors. The unique combinations of subunit pentamers manifest in distinct functional receptors. Using single-cell real-time quantitative RT-PCR, we identified the individual expression rates and co-expression rates of the different nAChR subunits in rat CA1 hippocampal interneurons in efforts to characterize functional receptors involved in learning and memory. The two-way combination of subunits with highest expression in hippocampal interneurons was α3β2. Moreover, this combination was expressed in ratios near 1:3 or 3:1 α3 to β2 respectively. To investigate the functionality of α3β2 receptors in different stoichiometries, we injected human α3 and rat β2 subunit mRNA in 1:3, 1:1, and 3:1 ratios into Xenopus laevis oocytes for expression. Two-electrode voltage clamp was then performed with the application of different concentrations of ACh to produce full dose-response curves and channel kinetics data. Distinct α3β2 functional channels were identified from the different expression ratios based on significant differences in channel kinetics (i.e.- peak current rise times, peak current decay times, steady state current in forced desensitization) Dose-response curves produced no significant difference in EC50 values in the different expression groups. However, there was a trend to greater agonist sensitivity with increased α3 expression relative to β2. α3β2 receptors were further characterized through forced desensitization of the receptors and generation of IV plots. The findings from this study elucidate the neuronal nAChR subunit combinations that form functional channels in hippocampal interneurons. nicotinic acetylcholine alpha3beta2 stoichiometries hippocampal interneurons dose-response Xenopus oocytes voltage-clamp Cell and Developmental Biology Physiology
6	Acetabularia-Rhodopsin, eine lichtgetriebene Protonenpumpe aus einem autotrophen Eukaryoten / Acetabularia rhodopsin, a light-driven proton pump from an autotrophic eukaryote Ewers, David 03 November 2005 (has links) No description available. 570 Biowissenschaften, Biologie Mathematics and Computer Science Acetabularia Bacteriorhodopsin Xenopus-Oocyten Protonenpumpe Acetabularia bacteriorhodopsin Xenopus oocytes proton pump 42.12 W
7	Functional characterization of urate handling by hSLC2A9 (hGLUT9) splice variants in a heterologous expression system Witkowska, Katarzyna Unknown Date No description available. GLUT9 SLC2A9 uric acid urate splice variants Xenopus oocytes heterologous expression solute transport simple carrier model facilitative glucose transporters GLUTs gout hyperuricemia
8	Transports de Na+ et K+ chez le riz : caractérisation de transporteurs et co-transporteurs de Na+ et K+ de la famille HKT / K+ and Na+ transports in rice : characterization of Na+ and K+ transporters and co-transporters of the HKT family Sassi, Ali 12 December 2011 (has links) Un prélèvement efficace de K+ à partir du sol est essentiel au développement des végétaux. Sur un sol riche en NaCl, le maintien d'un prélèvement sélectif et efficace de K+ à partir du sol et le contrôle de l'exportation de Na+ par la racine vers les feuilles constituent des fonctions essentielles pour la survie de la plante. Chez les plantes, les transporteurs HKT (High-affinity K+ Transporters) sont classés en deux sous-familles sur des bases phylogénétiques et de sélectivité ionique. Les membres de la sous-famille 1 transportent sélectivement Na+. Plusieurs d'entre eux ont été identifiés comme des acteurs majeurs de l'adaptation des plantes aux fortes salinités du sol en prévenant l'accumulation de Na+ dans les parties aériennes. Les membres de la sous-famille 2 co-transportent Na+ et K+. Leur rôle dans la plante, notamment dans le transport de K+, est encore mal compris. Je me suis intéressé à différents systèmes de transports de K+ et Na+, appartenant essentiellement à la famille HKT chez le riz. La caractérisation que j'ai effectuée a fait appel à plusieurs approches : électrophysiologie (voltage-clamp après expression en ovocyte de xénope), biologie cellulaire, génétique inverse et PCR en temps réel. L'analyse de l'expression par RT-PCR en temps réel de toute la famille HKT (4 membres dans chacune des deux sous-familles) a montré que ces transporteurs sont différemment exprimés au niveau des racines et des feuilles, et que leur niveau de transcrits est fortement et differentiellement régulé en conditions de stress salin ou osmotique et en présence d'hormones, ce qui suggère que ces différents systèmes jouent des rôles propres et diversifiés dans la plante. L'analyse plus détaillée d'OsHKT2;4, a montré par expression hétérologue dans l'ovocyte de xénope que ce système possède des propriétés fonctionnelles originales: il transporte sélectivement K+ à faibles concentrations de Na+, mais co-transporte Na+ et K+ à fortes concentrations de Na+ (>10 mM). L'analyse de l'expression d'OsHKT2;4 a révélé que ce transporteur est surexprimé en condition de carence en K+ et de stress salin, suggérant qu'OsHKT2;4 pourrait jouer un rôle important dans le transport de K+ dans ces deux conditions. Enfin, un patron d'expression nouveau pour un transporteur HKT a été révélé par l'analyse de plantes transgéniques exprimant le promoteur d'OsHKT2;4 fusionné aux gènes rapporteurs GUS ou GFP : en plus d'une localisation classique dans les tissus conducteurs, une forte expression est observée dans les stomates des gaines et des limbes foliaires, suggérant un rôle dans l'osmocontractilité de ces cellules.Mots clés: Oryza sativa, transport de potassium, transporteur HKT, Na+-K+ co-transporteur, électrophysiologie, ovocyte de xénope, localisation tissulaire, PCR quantitative, stress salin / Efficient uptake of K+ from the soil solution is essential for plant development. When plants are grown on a soil rich in NaCl, the maintenance of an efficient and selective uptake of K+ and the control of Na+ export from roots to shoots are crucial for plant survival. In plants, transporters belonging to the HKT (Highaffinity K+ Transport) family have been sorted in two subfamilies based on phylogenetic grounds and functional properties. Subfamily 1 members transport selectively Na+. Several of them have been shown to play major roles in plant adaptation to salt stress by preventing excessive accumulation of Na+ in shoots. Subfamily 2 members are thought to co-transport Na+ and K+, at least when expressed in heterologous systems. Their roles in planta, especially their potential role in K+ transport, are still largely unknown. I have been interested in different K+ and/or Na+ transport systems in rice, mostly belonging to the HKT family. For their characterization, different approaches have been used: electrophysiology (two-electrode voltage-clamp after expression in Xenopus oocytes), cell biology, reverse genetics and real-time PCR. Realtime RT-PCR analyses on the whole family of rice HKT transporters (4 members in both subfamilies) showed that the expression level in roots and leaves of these different systems is variable, and is differentially regulated by salt and osmotic stresses as well as by hormonal treatments, which suggests that these transporters have diverse and differentiated functions in the plant. A detailed analysis of OsHKT2;4 revealed original functional properties: this HKT transporter was indeed shown to be K+-selectively in the presence of low external Na+, but to switch to Na+ and K+ co-transport mode at high (>10 mM) Na+ concentrations. Expression analysis of OsHKT2;4 showed that this transporter is overexpressed upon salt stress and K+ shortage, which suggests that it could play an important role in K+ transport in these two conditions. At last, a new expression pattern for an HKT transporter was evidenced through the analysis of transgenic rice plants expressing OsHKT2;4 promoter fused to the GUS or GFP reporter genes: in addition to a classical localization in vascular tissues, expression of OsHKT2;4 was observed in stomata, suggesting a role for OsHKT2;4 in osmotic regulation in these cells Oryza sativa Transport de potassium Transporteur HKT Électrophysiologie Stress salin Ovocyte de xénope Oryza sativa Potassium transporter HKT transporter Electrophysiology Salt stress Xenopus oocytes Real-time PCR
9	Identification and Functional Characterization of Trans-acting Factors Involved in Vegetal mRNA Localization in Xenopus Oocytes / Mechanism of mRNA Localization in Xenopus Oocytes / Identifizierung und Funktionelle Charakterisierung Trans-agierender mRNA-Lokalisationsfaktoren in Xenopus Oozyten / Mechanismus der mRNA Lokalisation in Xenopus Oozyten Arthur, Patrick Kobina 27 June 2008 (has links) No description available. 500 Naturwissenschaften allgemein Mathematics and Computer Science Xenopus oozyten mRNA lokalisation Elav proteine XDead end mRNA RRM domäne Maternal mRNA RNA binde proteine RNA Transport Xenopus oocytes mRNA localization Elav proteins Xdead end mRNA RRM domain Maternal mRNA RNA binding proteins RNA Transport 42 WA
10	Spindle-Localized CPE-Mediated Translation Controls Mediotic Chromosome Segregation Eliscovich, Carolina 11 June 2008 (has links) La progresión meiótica y el desarrollo embrionario temprano están programados, en parte, por la activación tradcuccional de mRNAs maternos como lo son los que codifican para las proteinas de ciclina B1 o mos. Estos mRNAs no son traducidos al mismo tiempo ni en el mismo lugar. Por lo contrario, su traducción está especificamente regulada por elementos de poliadenilación citoplasmática (CPEs) presentes en sus 3'UTRs. Los elementos CPEs reclutan a la proteina de unión a CPE (CPE-binding protein CPEB (Colegrove-Otero et al., 2005; de Moor et al., 2005; Mendez and Richter, 2001; Richter, 2007)). Esta proteina de unión al RNA no sólo determina cuándo y en qué medida un mRNA será activado traduccionalmente por poliadenilación citoplasmática (Mendez et al., 2000a; Mendez et al., 2000b; Mendez et al., 2002) sino que también participa, junto con el represor de la traducción Maskin, en el transporte y la localización de sus mRNAs diana hacia los sitios de localización subcelular donde su traducción ocurrirá (Huang et al., 2003; Huang and Richter, 2004). Durante el desarrollo embrionario de Xenopus, CPEB se encuentra localizada en el polo animal de los oocitos y más tarde, sobre el huso mitótico y centrosomas en el embrión (Groisman et al., 2000). Se ha demostrado que embriones de Xenopus inyectados con agentes que interrumpen la traducción dependiente de poliadenilación citoplasmática, detienen la división celular y presentan estructuras mitóticas anormales (Groisman et al., 2000). En este trabajo que derivó en mi tesis doctoral, hemos demostrado que la activación traduccional localizada en el huso mitótico de mRNAs regulados por CPEB que codifican para proteinas con una conocida función en aspectos estructurales del ciclo celular como la formación del huso mitótico y la segregación cromosómica, es esencial para completar la primera división meiótica y para la correcta segregación cromosómica en oocitos de Xenopus. interkinesis microtubule organizing center microtubule-cytoskeleton chromosome segregation centrosomes spindle assembly germinal vesicle breakdown prophase-I arrest meiotic cell cycle progression Poly(A) tail lengthening animal and vegetal hemispheres xenopus oocytes and development RNA-binding proteins translational activation untranslated regions (UTRs) translational repression mRNA Localization Cytoplasmic polyadenylation translation CPEB vesícula Germinal profase-I formación del huso mitótico progresión del ciclo meiótico elongamiento de la cola de poli(A) polo animal y vegetal oocitos de Xenopus al RNA proteínas de unión regiones no traducidas (UTRs) activación traduccional citoesqueleto de microtúbulos localización de mRNAs represión traduccional poliadenilación citoplasmática traducción centro organizador de microtúbulos centrosomas segregación cromosómica Xkid TPX2 interquinesis CPEB Xkid TPX2 57

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