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Functional and molecular characterization of CtBP3 BARS, a protein involved in the control of the Golgi complexSpanò, Stefania January 2001 (has links)
No description available.
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Cystosolic proteins involved in the trafficking of TGN38Crump, Colin Michael January 1999 (has links)
No description available.
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Lysosome biogenesis during osteoclastogenesisApfeldorfer, Coralie 29 November 2006 (has links) (PDF)
Lysosomes are acidic, hydrolase-rich vesicles capable of degrading most biological macromolecules. During the past several decades, much has been learned about different aspects of lysosome biogenesis. The selective phosphorylation of mannose residues on lysosomal enzymes, in conjunction with specific receptors for the mannose-6-phosphate recognition marker, has been found to be largely responsible for the targeting of newly synthesized lysosomal enzymes to lyzosomes. It is known that lysosomes receive input from both the endocytotic and biosynthetic pathways. Nevertheless the exact molecular mechanisms responsible for sorting of the biosynthetic imput involved in the lysosome biogenesis is still a matter of debate. Because osteoclast precursors do not secrete their lysosomal enzymes and osteoclasts do, the observation of modifications occuring during osteoclastogenesis is a good model to observe mechanisms responsible for lysosomal enzymes traffic. Osteoclasts are bone-degrading cells. To perform this specific task they have to reorganise the sorting of their lysosomal enzymes to be able to target them toward the bone surface in mature cells. Since few years, the differentiation of osteoclasts in vitro did help to study these cells. Osteoclast morphology has been therefore already well studied, and the nature of their specific membrane domains is now established. Sensing the proximity of a bone-like surface the cell reorganises its cytoskeleton, and creates specific membrane domains: an actin-rich ring-like zone (named actin ring) surrounded by highly ruffled membrane (named the ruffled border) where enzymes are secreted, while subsequent bone degradation products are endocytosed. Endocytosed material is then transported through the cell inside transcytotic vesicles and released at the top of the cell in an area named the functional secretory domain. Several molecular machineries are thought to control these different phenomena. The main purpose of this thesis was to identify the major regulators of lysosomal enzymes secretion and therefore to identify the molecular switches responsible for such a membrane traffic re-organisation.
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Lysosome biogenesis during osteoclastogenesisApfeldorfer, Coralie 23 November 2006 (has links)
Lysosomes are acidic, hydrolase-rich vesicles capable of degrading most biological macromolecules. During the past several decades, much has been learned about different aspects of lysosome biogenesis. The selective phosphorylation of mannose residues on lysosomal enzymes, in conjunction with specific receptors for the mannose-6-phosphate recognition marker, has been found to be largely responsible for the targeting of newly synthesized lysosomal enzymes to lyzosomes. It is known that lysosomes receive input from both the endocytotic and biosynthetic pathways. Nevertheless the exact molecular mechanisms responsible for sorting of the biosynthetic imput involved in the lysosome biogenesis is still a matter of debate. Because osteoclast precursors do not secrete their lysosomal enzymes and osteoclasts do, the observation of modifications occuring during osteoclastogenesis is a good model to observe mechanisms responsible for lysosomal enzymes traffic. Osteoclasts are bone-degrading cells. To perform this specific task they have to reorganise the sorting of their lysosomal enzymes to be able to target them toward the bone surface in mature cells. Since few years, the differentiation of osteoclasts in vitro did help to study these cells. Osteoclast morphology has been therefore already well studied, and the nature of their specific membrane domains is now established. Sensing the proximity of a bone-like surface the cell reorganises its cytoskeleton, and creates specific membrane domains: an actin-rich ring-like zone (named actin ring) surrounded by highly ruffled membrane (named the ruffled border) where enzymes are secreted, while subsequent bone degradation products are endocytosed. Endocytosed material is then transported through the cell inside transcytotic vesicles and released at the top of the cell in an area named the functional secretory domain. Several molecular machineries are thought to control these different phenomena. The main purpose of this thesis was to identify the major regulators of lysosomal enzymes secretion and therefore to identify the molecular switches responsible for such a membrane traffic re-organisation.
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RAB-A2a dependent membrane traffic in Arabidopsis thalianaWoollard, Astrid Alexandra Diana January 2013 (has links)
Rab GTPases are major regulatory proteins of vesicle traffic and thus responsible for membrane identity, vesicle targeting and vesicle fusion. The angiosperm Rab GTPase family is grouped into eight clades (Rab-A to Rab-H) that are broadly conserved in animals and yeasts. It has been proposed that the Rab-A clade has diversified in land plants giving rise to six plant- specific structural subclasses, Rab-A1 to Rab-A6. Previous work suggests that the Arabidopsis Rab-A2 and Rab-A3 proteins define a novel endosomal compartment that lies on a pathway between the Golgi and the plasma membrane. In dividing cells, the Rab-A2/A3 compartment is implicated in biosynthetic traffic to the cell plate but it is unclear what traffics through this compartment in non-dividing cells. In this project, I investigated a range of membrane trafficking pathways in Arabidopsis thaliana. These were probed for dependency on RAB-A2a function, using the dominant negative approach combined with fluorescent marker technology. The data presented in this thesis suggests that RAB-A2a acts on a protein recycling pathway that is used by PIN2:GFP.
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Rôle des protéines SNARE au niveau de la vacuole bactérienne durant les phases précoces de l'infection par Yersinia pseudotuberculosis dans un contexte d'autophagie / SNAREs trafficking at bacteria vacuoles during early stages of Yersinia pseudotuberculosis infection in the context of autophagyLigeon, Laure-Anne 03 December 2013 (has links)
Yersinia pseudotuberculosis appartient à la famille des Enterobacteriaceae et peut être responsable de syndromes articulaires et digestifs. Au cours de la colonisation de l’hôte, une minorité des bactéries va, en plus de l’étape de multiplication extracellulaire présenter une phase de réplication intracellulaire dans les macrophages. Une partie des Y. pseudotuberculosis va se répliquer dans les macrophages en usurpant la voie de l’autophagie, afin de créer une niche réplicative au sein des autophagosomes bloqués dans leur maturation. Le trafic membranaire associé à l’infection de Y. pseudotuberculosis reste à ce jour peu caractérisé. Dans un premier temps, nous avons observé que lors de l’infection d’une cellule épithéliale par Y. pseudotuberculosis, la vacuole bactérienne est associée avec le marqueur des autophagosomes, la protéine LC3 mais de façon surprenante cette vacuole ne présente pas deux mais une membrane unique. Par ailleurs, nous avons montré que les protéines SNARE jouent un rôle majeur au cours du trafic intracellulaire de Y. pseudotuberculosis. VAMP3 et VAMP7 sont recrutées de manière séquentielle au niveau de la vacuole de Y. pseudotuberuclosis. VAMP7 va participer au recrutement de LC3 au niveau de la vacuole bactérienne et nous proposons que VAMP3 est un des constituants du check-point permettant l’adressage de la bactérie vers des vacuoles présentant une ou de multiple membranes positives pour LC3. Par la suite, nous nous sommes intéressés à la caractérisation des protéines de la voie autophagique et des endosomes, recrutées au niveau de la vacuole bactérienne à membrane unique et positive pour LC3. Nous avons mis en évidence que les protéines impliquées dans la formation de l’autophagosome et les marqueurs des endosomes précoces sont recrutées au niveau de la vacuole contenant Y. pseudotuberculosis. Cette vacuole positive pour LC3 va en suite acquérir les marqueurs des endosomes tardifs et du lysosome mais n’est pas acidifiée. En outre, nous avons initié des travaux sur un criblage en haut contenu afin d’identifier les partenaires des protéines SNARE et leurs rôles dans le trafic intracellulaire de Y. pseudotuberuclosis. Ces travaux démontrent l’importance de l’analyse de l’ultrastructure des compartiments positifs pour LC3. Ils illustrent comment la bactérie s’adapte à son environnement pour établir sa niche réplicative. Ils présentent enfin l’importance de la régulation de l’autophagie avec la première mise en évidence d’un check-point entre deux voies de compartimentation positives pour LC3 mais morphologiquement différentes. / Yersinia pseudotuberculosis is a member of the Enterobacteriaceae family. In human, Y. pseudotuberculosis infection is responsible for enteric and, in rare cases, erythema nodosum. During host colonization, a minor part of Y. pseudotuberculosis presents an intracellular replication step. Y. pseudotuberculosis can replicate inside macrophages by hijacking the autophagy pathway. The bacteria are able to block autophagosome maturation by acidification impairment, which allows to create a replicative niche. The membrane traffic during internalization of Yersinia remains poorly characterized. First, we highlighted that in epithelial cells, Y. pseudotuberculosis replicates mainly in vacuoles positive for LC3, a hallmark of autophagy. Surprisingly, this LC3-positive-vacuole presents only single limiting membrane. Second, we showed that SNARE proteins play a role in Y. pseudotuberculosis intracellular traffic. VAMP3 and VAMP7 are sequentially recruited to Yersinia-containing vacuoles (YCVs). VAMP7 is involved in the LC3 recruitment to YCVs with single- and double-membrane. We proposed that VAMP3 is a component of the molecular checkpoint for bacterial commitment to either single- or double-membrane LC3-positive pathway. Third, we characterized the traffic of endosomal proteins recruited to LC3-positive-YCV with single membrane in epithelial cells. We showed that markers of early endosome and proteins involved in autophagosome formation, are recruited to YCVs during the early stage of infection. Then, the vacuole acquire late endosomal and lysosomal proteins but acidification is not observed. Finally, we initiated a high-content screening approach for the identification of SNARE partners.Overall this work illustrates the importance of LC3-positive compartment ultrastructure analysis. Our result demonstrate how bacterial subvert the molecular machinery of the host in order to create a replicative niche. Finally, we present the importance of autophagy regulation by highlighting for the first times the existence of a molecular checkpoint between two LC3-positive vacuoles with different morphologies
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Regulation of GLUT4 Intrinsic Activity and Internalization in L6 Muscle CellsAntonescu, Costin N. 19 January 2009 (has links)
GLUT4 is the principal insulin-responsive glucose transporter in skeletal muscle. Insulin stimulation leads to exocytosis of intracellular GLUT4-containing vesicles to the cell surface, thereby increasing glucose uptake. Muscle contraction also elevates cell surface GLUT4 by a less understood mechanism. Once at the cell surface, GLUT4 may be subject to additional regulation, such as by modulation of its internalization rate or its intrinsic activity. The objective of this thesis was to identify the mechanism of GLUT4 internalization in muscle cells and to determine whether it is regulated by insulin treatment or by the signals elicited by muscle contraction. Skeletal muscle cells in culture stably expressing myc-tagged GLUT4 were used.
We found that GLUT4 internalizes simultaneously through a clathrin-dependent and a clathrin- and caveolae-independent and cholesterol- and dynamin-dependent pathway. Insulin did not regulate GLUT4 internalization. In contrast, mitochondrial uncoupling, which may mimic the heightened energy demand that occurs during muscle contraction, retarded GLUT4 internalization by inhibiting the clathrin-independent route. Activation of both AMP-dependent kinase (AMPK) and protein kinase C (PKC) was necessary and sufficient for this response.
We further hypothesized that the intrinsic activity of GLUT4 may be regulated under some conditions, based on a discrepancy between the amount of cell surface transporters and the rate of glucose uptake. In particular, inhibitors of p38 mitogen-activated protein kinase (p38MAPK) lowered insulin-dependent glucose uptake without reducing the number of GLUT4 units at the surface. We found that p38MAPK is activated by insulin through TAB1-dependent autophosphorylation, yet p38MAPK was dispensable for insulin-stimulated glucose uptake. Mechanisms other than p38MAPK must be involved in the regulation of GLUT4 intrinsic activity. In conclusion, in addition to its exocytosis, the activity and endocytosis of GLUT4 are regulated by stimuli that increase the rate of glucose uptake into muscle.
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Regulation of GLUT4 Intrinsic Activity and Internalization in L6 Muscle CellsAntonescu, Costin N. 19 January 2009 (has links)
GLUT4 is the principal insulin-responsive glucose transporter in skeletal muscle. Insulin stimulation leads to exocytosis of intracellular GLUT4-containing vesicles to the cell surface, thereby increasing glucose uptake. Muscle contraction also elevates cell surface GLUT4 by a less understood mechanism. Once at the cell surface, GLUT4 may be subject to additional regulation, such as by modulation of its internalization rate or its intrinsic activity. The objective of this thesis was to identify the mechanism of GLUT4 internalization in muscle cells and to determine whether it is regulated by insulin treatment or by the signals elicited by muscle contraction. Skeletal muscle cells in culture stably expressing myc-tagged GLUT4 were used.
We found that GLUT4 internalizes simultaneously through a clathrin-dependent and a clathrin- and caveolae-independent and cholesterol- and dynamin-dependent pathway. Insulin did not regulate GLUT4 internalization. In contrast, mitochondrial uncoupling, which may mimic the heightened energy demand that occurs during muscle contraction, retarded GLUT4 internalization by inhibiting the clathrin-independent route. Activation of both AMP-dependent kinase (AMPK) and protein kinase C (PKC) was necessary and sufficient for this response.
We further hypothesized that the intrinsic activity of GLUT4 may be regulated under some conditions, based on a discrepancy between the amount of cell surface transporters and the rate of glucose uptake. In particular, inhibitors of p38 mitogen-activated protein kinase (p38MAPK) lowered insulin-dependent glucose uptake without reducing the number of GLUT4 units at the surface. We found that p38MAPK is activated by insulin through TAB1-dependent autophosphorylation, yet p38MAPK was dispensable for insulin-stimulated glucose uptake. Mechanisms other than p38MAPK must be involved in the regulation of GLUT4 intrinsic activity. In conclusion, in addition to its exocytosis, the activity and endocytosis of GLUT4 are regulated by stimuli that increase the rate of glucose uptake into muscle.
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Contrôle spatio-temporel de la croissance filamenteuse chez Candida albicans / Temporal and spatial control of fungal filamentous growth in Candida albicansSilva, Patricia Maria de Oliveira e 22 May 2018 (has links)
Candida albicans est un pathogène fongique opportuniste de l’Homme, qui peut causer des infections superficielles mais aussi systémiques chez les patients immunodéprimés. Sa virulence est associée à sa capacité de changer d’une forme bourgeonnante à une forme hyphale. La petite GTPase de type Rho, Cdc42, est critique pour la croissance filamenteuse et, sous forme activée, sa localisation est restreinte à l’extrémité des hyphes. J’ai utilisé un système photoactivable, constitué des domaines d’Arabidopsis thaliana Cry2PHR-CibN, pour contrôler le recrutement de Cdc42 constitutivement actif à la membrane plasmique. J'ai déterminé comment le photo-recrutement de Cdc42 constitutivement actif perturbe la croissance filamenteuse et où, quand et comment une nouvelle croissance filamenteuse est ré-initiée. Mes résultats démontrent que, lors du photo-recrutement de Cdc42 constitutivement actif, l'extension du filament cesse puis un nouveau site de croissance s’établit dans la cellule. La localisation de ce nouveau site de croissance est corrélée à la longueur du filament. J'ai étudié les mécanismes moléculaires qui sous-tendent le désassemblage du site de croissance initial et l'emplacement spécifique du nouveau site de croissance filamenteuse. Dans les hyphes en croissance, un «cluster» de vésicules, appelé Spitzenkörper, est localisé à l'extrémité du filament. Lors du photo-recrutement de Cdc42 constitutivement actif, un nouveau «cluster» de vésicules, de composition similaire à celui du Spitzenkörper initial, apparaît dans la cellule mère. J'ai suivi la dynamique du Spitzenkörper et la localisation de Cdc42 sous forme activée, des sites d'endocytose, des vésicules de sécrétion et des câbles d’actine suite à la perturbation du site de croissance initial dans le filament. Dans l’ensemble, mes résultats indiquent qu'il existe une compétition pour la croissance entre le Spitzenkörper et le «cluster» de vésicules qui se forme immédiatement après le photo-recrutement de Cdc42 constitutivement actif et qu'un axe de polarité dynamique peut être établi en l'absence de croissance directionnelle. / Candida albicans is a fungal human pathogen that can cause life-threatening infections in immunocompromised patients, in part, due to its ability to switch between an oval budding form and a filamentous hyphal form. The small-Rho GTPase Cdc42 is crucial for filamentous growth and, in its active form, localizes as a tight cluster at the tips of growing hyphae. I have used a light-activated membrane recruitment system comprised of the Arabidopsis thaliana Cry2PHR-CibN domains to control the recruitment of constitutively active Cdc42 to the plasma membrane. I have determined how photorecruitment of constitutively active Cdc42 perturbs filamentous growth and where, when and how new filamentous growth is subsequently initiated. My results demonstrate that, upon photorecruitment of constitutively active Cdc42, filament extension is abrogated and a new growth site can be established in the cell. Location of a new filamentous growth site correlates with the length of the initial filament. I have investigated the molecular mechanisms that underlie the disassembly of an initial growth site and the specific location of the new filamentous growth site. In growing hyphae a cluster of vesicles, referred to as a Spitzenkörper, is localized at the tip of the filament. Upon photorecruitment of constitutively active Cdc42, a new cluster of vesicles, with a composition similar to that of the initial Spitzenkörper, appears in the mother cell. I have followed the dynamics of the Spitzenkörper, active Cdc42, sites of endocytosis, secretory vesicles and actin cables subsequent to disruption of the initial growth site in the filament. Taken together, my results suggest that there is competition for growth between the Spitzenkörper and the cluster of vesicles that forms immediately after the photorecruitment of constitutively active Cdc42 and that a dynamic polarity axis can be established in the absence of directional growth.
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Rôles des phosphoinositides dans l'intéraction membranaire de la protéine Rgd1 et la croissance polarisée des levures : étude structurale et interaction par RMN et cristallographie / Roles of phosphoinositides in the membrane interaction of the Rgd1 protein and the polarized growth of the yeast : structural study and interaction with NMR and X-Ray diffractionMartinez, Denis 05 December 2014 (has links)
Les phosphoinositides sont des molécules régulatrices présentes à l'interface membrane-cytosol, impliquées dans la transduction du signal, le trafic membranaire ainsi que l'organisation du cytosquelette. Ces lipides recrutent non seulement diverses protéines vers des compartiments spécifiques, mais régulent aussi leur activité enzymatique. Chez la levure Saccharomyces cerevisiae, ils interagissent directement avec le domaine RhoGAP de la protéine Rgd1, identifiée comme un activateur commun aux GTPases Rho3 et Rho4. Ces 2 protéines, respectivement impliquées dans la croissance polarisée et la cytocinèse, voient leur activité GTPasique exacerbée en présence de Rgd1pet des PIPs. L'objectif de cette thèse était comprendre à l'échelle moléculaire le processus unique d'activation de RhoGAP par les PIPs. Pour ce faire, nous avons réalisé l'étude structurale de RhoGAP par cristallographie couplée à la RMN en solution. Nos résultats montrent que le domaine possède les éléments essentiels à l'activation des protéines Rho. L'interaction avec les PIPs a été suivie par RMN en présence de PI(4)P et de PI(4,5)P2, respectivement localisés dans les vésicules de sécrétion et à la membrane plasmique. Nos résultats révèlent un site de liaison commun aux PIPs dans une région non conservée chez les domaines RhoGAP. L'affinité des complexes, de l'ordre de la centaine de micromolaires suggèrent qu'in vivo l'interaction soit transitoire et réversible avec les PIPs. La sélectivité de l'interaction se ferait donc de façon spatio-temporelle, au niveau des vésicules de sécrétion pour la croissance polarisée et de la membrane plasmique pour la cytocinèse. / Phosphoinositides act as regulatory and signalling molecules at the membrane-cytosol interface in signal transduction, membrane traffic and cytoskeleton organization. These lipids recruit several proteins to specific compartments, but also regulate their activity. In the yeast Saccharomycescerevisiae, they directly bind the Rgd1-RhoGAP domain, that stimulates the GTPase activity of bothRho3p and Rho4p. The GTPase activity of these two Rho proteins, respectively involved in the polarized growth and cytokinesis of the yeast, is enhanced with the presence of Rgd1p and PIPs. The main objective of this thesis is to understand the PIP-RhoGAP interaction at the molecular level. In order to do that, we coupled X-ray structure determination to solution NMR spectroscopy on the isolated RhoGAP domain. Our results show that the domain contains the conserved elements that would usually confer the catalytic GTPase activation. We us e liquid-state NMR spectroscopy to follow the interaction with PI(4)P and PI(4,5)P2, respectively found in secretion vesicles and the plasma membrane. Our study reveals a common binding site for both PIPs in a non-conserved region in the RhoGAP domain family. We measured sub-millimolar binding affinity for PIPs. Such moderate binding affinities are consistent with the biological requirement for reversible complex formation. The selectivity of the interaction could be made in a spatio temporal way, on the secretion vesicles during polarized growth and at the plasma membrane during cytokinesis.
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