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Organization of secretion components in bacillus subtilis / Organisation de composants de la sécrétion dans Bacillus subtilisMackichan, Calum 16 July 2013 (has links)
La membrane bactérienne a fait l'objet de nombreuses études de localisation de protéines et de phospholipides. Par fusion d’une protéine fluorescente (GFP) aux gènes d’intérêt, il est alors possible d‘observer la localisation des protéines associées par microscopie. La plupart de ces observations ont été réalisées à l’aide de microscopes dits à épifluorescence. Afin d’obtenir une qualité d’image suffisante, il était nécessaire de surexprimer la protéine observée, insérée à un locus ectopique non naturel. Ce travail de thèse a permis d’utiliser une nouvelle technologie acquise dans notre laboratoire, le microscope à fluorescence par réflexion totale interne (TIRFM), plus puissant que le microscope à épifluorescence utilisé précédemment. Cette technologie a permis une caractérisation plus détaillée de la localisation de protéines d’intérêt, placées sous contrôle de leur promoteur naturel. Il a également été possible de caractériser la dynamique des foci observés. Nous avons concentré notre étude sur 3 protéines: (i) SecA pour l’étude de la translocation des protéines du cytoplasme vers la membrane, (ii) YidC pour l’insertion des protéines dans la membrane, (iii) PgsA pour la synthèse des phospholipids. Les foci se déplacent dynamiquement et s’associent de manière transitoire dans la membrane. L’observation sur la durée de ces foci, et l’analyse de leur intensité moyenne au cours des observations, montre que SecA se déplace sur l’ensemble de la membrane de manière uniforme. L’analyse du déplacement des foci montre une relation quadratique entre la distance moyenne parcourue par les foci en fonction du temps. Ce résultat est en accord avec l’hypothèse d’un mouvement brownien des foci. Les foci sont observés dans les différentes phases de croissance des cellules, et le nombre de foci présents dans une cellule de la longueur de celle-ci. SecA-GFP a été testés dans un certain nombre de contextes génétiques. La localisation a été perturbée lors de la déplétion de pgsA. Cependant, comme PgsA est une protéine essentielle, il ne peut être exclu que ce changement de localisation apparaît des cellules qui sont mortes ou mourantes. Dans une souche mutante ΔclsA, on n’observe aucune différence dans la localisation de SecA en phase exponentielle, mais on aperçoit une relocalisation aux poles en phase stationnaire de croissance. La voie Tat est responsable du transport des protéines devant être exportées dans un état structuré, par exemple dans le cas de l’incorporation d’un co-facteur. À ce jour, la régulation du système Tat est peu connues, de même que les interactions entre les différentes sous-unités du système Tat et d'autres protéines dans le cytoplasme, dans la membrane ou dans la paroi cellulaire. Des fusions de les gènes de la voie Tat ont été co-exprimées deux à deux dans des cellules de levure, et leur capacité à interagir in vivo a été testée par la méthode dite du double hybride chez la levure. Nous avons généré un réseau d’interaction autour des cinq composants de système Tat. Pour déterminer les implications fonctionnelles des composants du réseau, nous avons travaillé en collaboration avec le laboratoire de Jan-Maarten van Dijl. Nous avons utilisé une collection de souches mutantes pour lesquels certains composants individuels du réseau ont été retires. Trois a été observe d’etre nécessaires pour la sécrétion Tat-dépendante. Nous avons étudié la localisation des fusions GFP avec ces proteins. On a observé une localisation double de HemAT selon l’état physiologique de la cellule. En phase exponentielle, les cellules de B. subtilis sont généralement présentes sous forme de chaînes dans lesquelles le septum de division a déjà été formé, mais la séparation cellulaire n'a pas encore eu lieu. Une fusion de la GFP à CsbC apparaît de façon homogène dans la membrane. / In the years since the cloning of GFP, the field of bacterial cell biology has characterized a variety of specific protein localization patterns in the bacterial membrane. The vast majority of early subcellular localization studies made use of inducible GFP fusions, which generally required the presence of high concentrations of inducer, and can therefore be considered to be overexpressed. An outstanding question remains over the organization of natively expressed proteins in the membrane. Here, we have investigated the localization of functional GFP fusions to proteins catalyzing important membrane processes; the secretion motor protein SecA, the membrane insertase YidC1, and the essential phospholipid synthase PgsA using total internal reflection fluorescence microscopy (TIRFM). This allowed natively expressed proteins to be localized with temporal resolution that can capture their dynamics. We characterized dynamic complexes dispersed throughout the membrane displaying diffusive movement with no preferred trajectories. Further characterization focused upon identifying conditions in which the localization pattern was disturbed. A polar mislocalization was identified in a cardiolipin mutant strain. The yeast two-hybrid (Y2H) approach is a robust approach to detect binary interactions on a proteome-scale. We performed genome-wide Y2H screens as well as targeted Y2H analyses for specific interactions involving components of the Sec and Tat secretion machineries of B. subtilis, revealing an intricate protein-protein interaction network involving 71 proteins. Furthermore, three proteins identified in the Tat network, WprA, CsbC and HemAT, were shown to be important for effective protein secretion via the B. subtilis Tat system, indicating that our yeast two hybrid assays reveal biologically significant interactions involving membrane proteins. The studies provide a novel proteomic view on the interaction network of the secretion systems of B. subtilis.
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Etude fonctionnelle dun oncogène humain impliqué dans le Sarcome dEwing, oncTre210, homologue à deux gènes levuriens, MSB3 et MSB4Dechamps, Christophe 23 April 2009 (has links)
Dechamps Christophe (2008). Etude fonctionnelle dun oncogène humain impliqué dans le Sarcome dEwing, oncTre210, homologue à deux gènes levuriens, MSB3 et MSB4 (thèse de doctorat). Gembloux, Faculté Universitaire des Sciences Agronomiques, 173 p., 12 tabl., 40 fig.
Résumé : Le produit de l'oncogène humain oncTre210 est apparenté, par sa structure primaire, aux protéines Ypt/Rab GAP (GTPase Activating Proteins spécifiques des Ypt/Rab GTPases). En effet, sa région N-terminale, qui est fortement homologue aux deux GAP de Saccharomyces cerevisiae Msb3p et Msb4p, renferme le domaine catalytique TBC, hautement conservé, des Ypt/Rab GAP. Les protéines Msb3p et Msb4p de Saccharomyces cerevisiae font partie de la famille des GTPase activating protein (GAP) spécifique aux Ypt/Rab GTPase. Elles sont primordiales au trafic vésiculaire et sont impliquées dans la régulation de l'exocytose et dans l'organisation du cytosquelette d'actine. Mais, leurs rôles biologiques exacts nont jamais été déterminés. La délétion simultanée des 2 gènes MSB3 et MSB4 dans la levure S. cerevisiae induit une inhibition de croissance de la levure sur un milieu de culture contenant du DMSO et/ou de la caféine, perturbe lorganisation du cytosquelette dactine, produit une anomalie de bourgeonnement dans la levure diploïde et affecte la ségrégation des noyaux. Pour trouver des composants qui interagissent génétiquement avec les produits des gènes MSB3 et MSB4, nous avons criblé une banque génomique pour des suppresseurs homologues extragéniques multicopies restaurant la croissance du double mutant levurien msb3 msb4 en présence de DMSO et/ou de caféine. Sept gènes ont ainsi été identifiés après une série de vérifications. Ces 7 suppresseurs peuvent être classés pour la fonction biologique de leurs produits en plusieurs classes : transport vésiculaire, cycle cellulaire, chaperon moléculaire, protéasome et ARN ribosomial. Ces résultats nous permettent d'identifier les voies physiologiques où les deux protéines Msb3p et Msb4p seraient impliquées. Le produit de l'oncogène oncTre210 est impliqué dans différents cancers humains dont le sarcome d'Ewing. Pour létude des partenaires interagissant avec lune ou lautre des deux parties de la protéine de fusion oncTre210p, nous avons utilisé le système double-hybride en levure en utilisant différentes banques d'expression. Un grand nombre de partenaires protéiques a été isolé comme interagissant avec l'oncoprotéine. Deux protéines impliquées dans l'organisation et la structure du cytosquelette ont été choisies parmi les partenaires de l'oncoprotéine pour être étudiées. L'interaction de ces deux protéines avec la partie GAP de oncTre210p a été confirmée par les techniques de GST pulldown, de co-immunoprécipitation et de co-localisation. Ces protéines identifiées comme interagissant avec la partie GAP sont la chaîne légère régulatrice de la myosine II (Myl2) et LOC91256, protéine contenant des motifs ankyrine. A partir de ces observations un nouveau rôle de l'oncoprotéine oncTre210p a été suggéré. L'ensemble de nos résultats ainsi que des données expérimentales acquises par d'autres équipes internationales nous a permis de proposer un modèle d'action pour l'oncoprotéine oncTre210p.
Dechamps Christophe (2008). Functional study of an oncogene implicated in Ewing's sarcoma, oncTre210, a human homologue of two yeast genes, MSB3 and MSB4 (Thesis in French). Gembloux, Belgium, Gembloux Agricultural University, 173 p., 12 tabl., 40 fig.
Summary : The oncTre210 oncogene product is structurally related to the Ypt/Rab GTPase-Activating Proteins (Ypt/Rab GAPs). Particularly, the N-terminal region of the oncoprotein shares with the yeast proteins Msb3p and Msb4p the highly conserved TBC domain, forming the catalytically active domain of Ypt/Rab GAPs. The Msb3p and Msb4p proteins of Saccharomyces cerevisiae are members of the Ypt/Rab-specific GTPase activating protein (GAP) family. They are important to vesicular trafficking and involved in the regulation of exocytosis and in the organization of the actin cytoskeleton, but their exact biological roles have yet to be determined. The msb3 msb4 yeast double mutation causes growth inhibition in the presence of DMSO and/or caffeine, affects the organization of the actin cytoskeleton, produces a random budding pattern in diploid cells, and affects segregation of the nucleus. To find cell components that interact genetically with the products of the MSB3 and MSB4 genes, we screened a genomic library for multicopy suppressor genes restoring normal growth of the double mutant in the presence of DMSO and caffeine. Six genes were identified, and the extent to which each gene corrects specific growth defects of the msb3 msb4 mutant is described. The encoded suppressors were classified on the basis of functional features into five groups: vesicular transport, cell division, molecular chaperon, proteasome and ribosomal RNA. These results allow us to identify the physiologic ways where the Msb3p and Msb4p proteins are implicated. The product of the oncTre210 oncogene is involved in various human cancers, including Ewings sarcoma. In order to identify proteins interacting with the two parts of this protein, we performed yeast two-hybrid screening of various libraries. A large number of proteins was identified to be partners of the oncogene product. Two components of the cytoskeleton were chosen to be studied, whose interaction with the GAP region was confirmed by GST-pulldown, co-immunoprecipitation, and colocalisation experiments. The proteins found to interact with the GAP region are the light regulatory chain of myosin II (Myl2) and LOC91256, a protein containing ankyrin repeats. From these observations a new role for the oncTre210p oncoprotein in cytokinesis was suggested. Our results and data from other international teams allow us to propose a model for the action of the oncTre210 oncogene product.
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Characterization of the Ubc13-Mms2 Lysine-63-linked ubiquitin conjugating complexPastushok, Landon Keith 01 May 2006
Ubiquitylation is an indispensable post-translational modification system in eukaryotic cells that leads to the covalent attachment of a small ubiquitin (Ub) protein onto a target. The traditional and best-characterized role for ubiquitylation is a fundamental regulatory mechanism whereby target proteins are tagged with a characteristic Lys48-linked Ub chain that signals for their elimination through proteasomal degradation. Challenging this conventional wisdom is the finding that some ubiquitylated proteins are modified by Ub chains linked through Lys63, providing a molecular signal that is thought to be structurally and functionally distinct from Lys48-linked Ub chains. Of further interest and significance is that the Lys63-linked Ub chains are apparently synthesized through a novel biochemical mechanism employing a unique complex formed between a true Ub conjugating enzyme (E2), Ubc13, and an E2-variant (Uev), Mms2 (or Uev1A). The goal of this thesis was to employ structural and functional approaches in order to better characterize the Ubc13-Mms2 Lys63-linked Ub conjugation complex. <p>Error-free DNA damage tolerance (DDT) in the budding yeast is dependent on Lys63-linked Ub chains synthesized by Ubc13-Mms2 and thus provided the opportunity to experimentally test the function of the human UBC13 and MMS2 genes in a simple model organism. Human UBC13 and MMS2 were each shown to function in place of their yeast counterparts and in accordance, human Ubc13 was shown to physically interact with yeast Mms2, and vice versa. Two human MMS2 homologs were also tested and it was determined that UEV1A but not UEV1B can function in place of mms2 in yeast DDT. Physical interactions were observed between Ubc13 and Uev1A, but not between Ubc13 and Uev1B, suggesting that Ubc13-Uev complex formation is required for function. <p>In collaboration with a research group at the University of Alberta, crystal structure and NMR data were used to develop a mechanistic model for the conjugation of Lys63-linked Ub chains by the Ubc13-Mms2 heterodimer, whereby the special orientation of two Ub molecules facilitates a specific Ub-Ub linkage via Lys63. In order to help support the in vitro model and to determine how the Ubc13-Mms2 structure relates to biological function, I used a structure-based approach to direct the creation of point mutations within four key regions of the Ubc13-Mms2 heterodimer; the Ubc13 active-site, the Ubc13-E3 (Ub ligating enzyme) interface, the Mms2-Ub interface, and the Ubc13-Mms2 interface. <p>Underscoring the importance of the Ub conjugation by Ubc13-Mms2, a Ubc13-C87S active-site mutation was created that could bind to Mms2 but was unable to function in DDT. Regarding the Ubc13-E3 interface, a single Ubc13-M64A point mutation had a potent effect on disrupting Ubc13 function in DDT, as well as its physical interaction with Rad5, TRAF6, and CHFR. The results suggest that different RING finger E3s use the same Ubc13 surface to sequester the Ub conjugation activity of Ubc13-Mms2. Two human Mms2 mutations at Ser32 and Ile62, which are contained within the Mms2-Ub interface, were found to reduce the ability of Mms2 to bind Ub. When the corresponding yeast mutations are combined, a synergistic loss in DDT function is observed. The relative orientation of Ser32 and Ile62 suggests that the Mms2 and Tsg101 Uev families use different Uev surfaces to physically interact with Ub. A 200 ìM dissociation constant for the wild-type Mms2-Ub interaction was also determined. The systematic mutagenesis and testing of 14 Ubc13-Mms2 interface residues led to mutants with partial or complete disruption of binding and function. Using this data, a model involving the insertion of a specific Mms2-Phe residue into a unique Ubc13 hydrophobic pocket was created to explain the specificity of Mms2 for Ubc13, and not other E2s. In addition, the dissociation constant for the wild-type Ubc13-Mms2 heterodimer was determined to be approximately 50 nM. <p>The structural and functional studies strongly support the notion that Ubc13-Mms2 complex has the unique ability to conjugate Lys63-linked Ub chains. However, several reported instances of Lys63-linked Ub chains in vivo have not yet been attributed to Ubc13 or Mms2. To address the disparity I was able to demonstrate and map a physical interaction between Mms2 and Rsp5, an E3 implicated in Lys63-linked Ub conjugation. Surprisingly, it was found that MMS2 is not responsible for the RSP5-dependent Lys63-linked Ub conjugation of a plasma membrane protein. A possible explanation for the apparent paradox is presented.
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Characterization of the Ubc13-Mms2 Lysine-63-linked ubiquitin conjugating complexPastushok, Landon Keith 01 May 2006 (has links)
Ubiquitylation is an indispensable post-translational modification system in eukaryotic cells that leads to the covalent attachment of a small ubiquitin (Ub) protein onto a target. The traditional and best-characterized role for ubiquitylation is a fundamental regulatory mechanism whereby target proteins are tagged with a characteristic Lys48-linked Ub chain that signals for their elimination through proteasomal degradation. Challenging this conventional wisdom is the finding that some ubiquitylated proteins are modified by Ub chains linked through Lys63, providing a molecular signal that is thought to be structurally and functionally distinct from Lys48-linked Ub chains. Of further interest and significance is that the Lys63-linked Ub chains are apparently synthesized through a novel biochemical mechanism employing a unique complex formed between a true Ub conjugating enzyme (E2), Ubc13, and an E2-variant (Uev), Mms2 (or Uev1A). The goal of this thesis was to employ structural and functional approaches in order to better characterize the Ubc13-Mms2 Lys63-linked Ub conjugation complex. <p>Error-free DNA damage tolerance (DDT) in the budding yeast is dependent on Lys63-linked Ub chains synthesized by Ubc13-Mms2 and thus provided the opportunity to experimentally test the function of the human UBC13 and MMS2 genes in a simple model organism. Human UBC13 and MMS2 were each shown to function in place of their yeast counterparts and in accordance, human Ubc13 was shown to physically interact with yeast Mms2, and vice versa. Two human MMS2 homologs were also tested and it was determined that UEV1A but not UEV1B can function in place of mms2 in yeast DDT. Physical interactions were observed between Ubc13 and Uev1A, but not between Ubc13 and Uev1B, suggesting that Ubc13-Uev complex formation is required for function. <p>In collaboration with a research group at the University of Alberta, crystal structure and NMR data were used to develop a mechanistic model for the conjugation of Lys63-linked Ub chains by the Ubc13-Mms2 heterodimer, whereby the special orientation of two Ub molecules facilitates a specific Ub-Ub linkage via Lys63. In order to help support the in vitro model and to determine how the Ubc13-Mms2 structure relates to biological function, I used a structure-based approach to direct the creation of point mutations within four key regions of the Ubc13-Mms2 heterodimer; the Ubc13 active-site, the Ubc13-E3 (Ub ligating enzyme) interface, the Mms2-Ub interface, and the Ubc13-Mms2 interface. <p>Underscoring the importance of the Ub conjugation by Ubc13-Mms2, a Ubc13-C87S active-site mutation was created that could bind to Mms2 but was unable to function in DDT. Regarding the Ubc13-E3 interface, a single Ubc13-M64A point mutation had a potent effect on disrupting Ubc13 function in DDT, as well as its physical interaction with Rad5, TRAF6, and CHFR. The results suggest that different RING finger E3s use the same Ubc13 surface to sequester the Ub conjugation activity of Ubc13-Mms2. Two human Mms2 mutations at Ser32 and Ile62, which are contained within the Mms2-Ub interface, were found to reduce the ability of Mms2 to bind Ub. When the corresponding yeast mutations are combined, a synergistic loss in DDT function is observed. The relative orientation of Ser32 and Ile62 suggests that the Mms2 and Tsg101 Uev families use different Uev surfaces to physically interact with Ub. A 200 ìM dissociation constant for the wild-type Mms2-Ub interaction was also determined. The systematic mutagenesis and testing of 14 Ubc13-Mms2 interface residues led to mutants with partial or complete disruption of binding and function. Using this data, a model involving the insertion of a specific Mms2-Phe residue into a unique Ubc13 hydrophobic pocket was created to explain the specificity of Mms2 for Ubc13, and not other E2s. In addition, the dissociation constant for the wild-type Ubc13-Mms2 heterodimer was determined to be approximately 50 nM. <p>The structural and functional studies strongly support the notion that Ubc13-Mms2 complex has the unique ability to conjugate Lys63-linked Ub chains. However, several reported instances of Lys63-linked Ub chains in vivo have not yet been attributed to Ubc13 or Mms2. To address the disparity I was able to demonstrate and map a physical interaction between Mms2 and Rsp5, an E3 implicated in Lys63-linked Ub conjugation. Surprisingly, it was found that MMS2 is not responsible for the RSP5-dependent Lys63-linked Ub conjugation of a plasma membrane protein. A possible explanation for the apparent paradox is presented.
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Engineering the pregnane X receptor and estrogen receptor alpha to bind novel small molecules using negative chemical complementationShaffer, Hally A. 05 April 2011 (has links)
Nuclear receptors are ligand-activated transcription factors that play significant roles in various biological processes within the body, such as cell development, hormone metabolism, reproduction, and cardiac function. As transcription factors, nuclear receptors are involved in many diseases, such as diabetes, cancer, and arthritis, resulting in approximately 10-15% of the pharmaceutical drugs presently on the market being targeted toward nuclear receptors. Structurally, nuclear receptors consist of a DNA-binding domain (DBD), responsible for binding specific sequences of DNA called response elements, fused to a ligand-binding domain (LBD) through a hinge region. The LBD binds a small molecule ligand. Upon ligand binding, the LBD changes to an active conformation leading to the recruitment of coactivator (CoAC) proteins and initiation of transcription. As a result of their involvement in disease, there is an emphasis on engineering nuclear receptors for applications in gene therapy, drug discovery and metabolic engineering.
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Caractérisation biochimique et moléculaire du complexe SCF (SKP1-CULLIN-FBOX) chez le blé tendre / Biochemical and molecular characterization of the SCF complex (SKP1-CULLIN-FBOX) in soft wheatEl Beji, Imen 18 July 2011 (has links)
Les modifications post-traductionnelles des protéines constituent un niveau crucial de régulation de l’expression des gènes. Parmi elles, la conjugaison peptidique impliquant l’ubiquitine intervient entre autre dans la régulation de la stabilité protéique. La fixation de ce peptide de 76 acides aminés, extrêmement conservé, sous forme de chaîne de polyubiquitine, nécessite l’intervention de trois enzymes (E1, E2 et E3) et constitue un signal de dégradation de la protéine ainsi modifiée. Cette voie de régulation intervient dans de très nombreux processus biologiques. Les complexes SCF sont impliqués dans la voie de protéolyse ciblée. Ils représentent l' une des classes les plus fréquentes d'ubiquitine ligase E3 et ils sont composés de quatre sous-unités (Rbx, Cullin, SKP1, et F-box). La structure et la fonction des complexes SCF, ont été étudiées chez la levure, l’Homme et la plante modèle A. thaliana. Cependant, peu de travaux ont été réalisés chez des plantes cultivées, en particulier les céréales, telles que le blé. Cinq gènes codant pour la sous-unité Skp1 (TSK1, TSK3, TSK6, TSK11 et TSK16), cinq gènes codant pour la sous-unité F-box (ZTL, ATFBL5, EBF, TIR1 et ABA-T), un gène codant pour la sous-unité Cullin1 et un gène codant pour la protéine RBX du complexe SCF du blé, ont été isolés et clonés. Les différents tests d’interaction entre les quatre sous-unités du complexe SCF ont été réalisés par la méthode du double-hybride dans la levure en utilisant la technologie Gateway. Ces études ont montré que les deux protéines, TSK1 et TSK3, fixent spécifiquement différentes sous-unités F-box. Parallèlement, nous avons montré que la protéine TSK11 représente une structure particulière. Des études d’insertion/délétion sur la protéine TSK11 ont permis d’identifier un nouveau domaine indispensable à l’interaction. Les analyses par PCR semi-quantitative des différents gènes codant pour la sous-unité Skp1, dans trois tissus différents (feuille tige et racine), ont mis en évidence une expression constitutive des gènes TSK3, TSK6 et TSK11. Tandis que les gènes TSK1 et TSK16 sont exprimés préférentiellement dans les racines. Les analyses par PCR semi-quantitative sur des plantules de blé à différents stades de développement, ont mis en évidence une surexpression du gène TSK11 au moment de la floraison. Ce qui suggère que TSK11 est probablement un équivalent fonctionnel d’ASK1 chez Arabidopsis thaliana. / The selective degradation of proteins is an important means of regulating gene expression and plays crucial roles in the control of various cellular processes. The Ubiquitin (Ub)–Proteasome System (UPS) is the principal non-lysosomal proteolytic pathway in eukaryotic cells and is required for the degradation of key regulatory proteins. Ubiquitin is a 76-residue protein that can be attached covalently to target proteins through an enzymatic conjugation cascade involving three enzymes denoted, E1, E2 and E3.The SCF complex is a type of ubiquitin-protein ligase (E3) that acts as the specific factor responsible for substrate recognition and ubiquitination. Some polyubiquitinated proteins are then targeted to the 26S proteasome for degradation. The SCF complex consists of four components including SKP1, Cullin1, Rbx1 and a large gene family of F-box proteins. Twenty one SKP1-related genes have been described in the Arabidopsis genome and some of these genes have been analyzed genetically. By contrast, little is known about the function and structure of SKP1 homologues in wheat. Some of the Triticum SKP1-related protein (TSKs) have been characterized in this study. Five complete sequences of SKP1 (TSK1, TSK3, TSK6, TSK11 and TSK16), five F-box (ZTL, ATFBL5, EBF, TIR1 and ABA-T), one Cullin1 and one Rbx, were successfully cloned and biochemically characterized. Yeast two-hybrid analysis showed that TSK1 and TSK3 are capable of interacting with different F-box proteins. Furthermore, TSK11 contains an additional domain that changed its interaction capabilities. In vitro analysis using a chimeric protein showed that this additional domain could modify the interaction between a SKP-like protein and two F-box proteins. Expression analyses revealed that TSK1 and TSK16 were expressed predominantly in roots. While, TSK3, TSK6 and TSK11 were expressed in several wheat organs. In addition, the TSK11 was up-regulated in the leaves at the flowering stage.
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Caracterização das proteinas TIPRL e alfa4, reguladores de fosfatases 2A / Characterization of the type 2A phosphatase regulatory protein, TIPRL and alpha4Smetana, Juliana Helena Costa 13 August 2018 (has links)
Orientador: Nilson Ivo Tonin Zanchin / Tese (doutorado) - Universidade Estadual de Campinas, Instituto de Biologia / Made available in DSpace on 2018-08-13T09:08:00Z (GMT). No. of bitstreams: 1
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Previous issue date: 2009 / Resumo: As células respondem constantemente a uma enorme variedade de estímulos, que são interpretados e integrados por meio de redes de sinalização, dando origem a uma resposta biológica. Defeitos nesses circuitos são a causa de diversas doenças, incluindo muitos, se não
todos os tipos de câncer. As fosfatases, enzimas que removem grupamentos fosfato dos substratos de quinases, dependem principalmente de subunidades regulatórias para definir sua especificidade. As fosfatases do tipo 2A constituem a subfamília PPP, que é formada por PP2A, PP4 e PP6. PP2A é a principal fosfatase solúvel de fosfosserina e fosfotreonina em células animais e é encontrada predominantemente como uma holoenzima formada por uma subunidade catalítica (C), uma subunidade regulatória (B, B', B'' ou B''') e uma de ancoragem (PR65/A). Em levedura, as fosfatases 2A desempenham um importante papel na via da quinase TOR, o que
ocorre por meio da proteína essencial Tap42. A proteína Tip41 foi identificada como um parceiro de interação de Tap42 e regulador da via da quinase TOR em levedura. A homóloga de Tap42 em mamíferos, chamada de a4, está envolvida na regulação de diversos processos celulares, como
diferenciação, desenvolvimento, migração celular e apoptose, por meio de seu papel conservado de regulador de fosfatases 2A. A homóloga em mamíferos de Tip41, chamada TIPRL, é uma proteína ainda pouco caracterizada. Este trabalho teve como objetivo analisar a função das
proteínas a4 e TIPRL humanas e esclarecer seu papel na regulação de fosfatases 2A. A caracterização estrutural de a4 e Tap42, usando dados de SAXS, dicroísmo circular e proteólise limitada, mostrou que essas proteínas apresentam um domínio N-terminal compacto formado por a-hélices e um domínio C-terminal desestruturado. Em uma triagem de interações com a proteína TIPRL humana, identificamos as fosfatases PP2Ac, PP4c e PP6c como seus parceiros de interação, assim como os fatores de transcrição MafB e TAF10. Ao contrário do esperado a partir do modelo de levedura, a4 e TIPRL não interagem diretamente, mas formam um complexo ternário com PP2Ac. Uma triagem de substratos de fosfatases 2A regulador por TIPRL
identificou os fatores de splicing SF2/ASF e SF2p32. Nossos resultados sugerem um modelo estrutural para a regulação das fosfatases 2A por a4 e mostram que TIPRL é um novo regulador comum dessas fosfatases com funções na regulação da expressão gênica. / Abstract: Cells respond constantly to a variety of stimuli, which are interpreted and integrated through signaling networks, giving rise to biological responses. Defects in this circuitry are a cause of many diseases, including cancer. Protein phosphatases are enzymes which remove
phosphate groups from kinase substrates, relying mainly on regulatory subunits for their substrate specificity. Type 2A phosphatases belong to the PPP subfamily, which is formed by PP2A, PP4 and PP6. PP2A is the major soluble serine/threonine phosphatase in animal cells and is found
predominantly as a heterotrimer composed of a catalytic (C), a regulatory (B, B', B'' or B''') and a scaffold (PR65/A) subunit. Type 2A phosphatases play a major role in the yeast TOR signaling pathway through their interaction with the essential protein Tap42. Tip41 was identified as a Tap42 interacting protein and regulator of the TOR pathway. a4, the mammalian orthologue of
Tap42, regulates many cellular processes such as differentiation, development, cell migration and apoptosis as a conserved type 2A phosphatase regulator. TIPRL, the mammalian orthologue of Tip41, is still poorly characterized. The objective of the present work was to analyse the function of a4 and TIPRL and improve the understanding of their role as type 2A phosphatase regulators. The structural characterization of a4 using SAXS analyses, circular dichroism and limited proteolysis, showed that these proteins are formed by an a-helical N-terminal domain and an unfolded C-terminal domain. A screen for TIPRL interacting proteins identified PP2Ac, PP4c and PP6c and also the transcription factors MafB and TAF10. Unlike their yeast conterparts, a4 and TIPRL do not interact directly, but rather form a ternary complex with PP2A. A search for type 2A phosphatase substrates regulated by TIPRL identified the splicing factor SF2/ASF and its
regulatory protein SF2p32. Our results suggest a structural model for the regulation of type 2A phosphatases by a4 and show that TIPRL is a novel common regulator of these phosphatases which functions in regulation of gene expression. / Doutorado / Genetica Animal e Evolução / Doutor em Genetica e Biologia Molecular
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Estudo funcional e estrutural de Nip7p, uma proteina conservada envolvida na sintese de ribossomos / Functional and structural analysis of Nip7p, a conserved protein involved in ribosome biogenesisColtri, Patricia Pereira 12 October 2007 (has links)
Orientador: Nilson Ivo Tonin Zanchin / Tese (doutorado) - Universidade Estadual de Campinas, Instituto de Biologia / Made available in DSpace on 2018-08-09T15:29:14Z (GMT). No. of bitstreams: 1
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Previous issue date: 2007 / Resumo: A síntese de ribossomos é um processo conservado em eucariotos e se inicia com a transcrição dos rRNAs no nucléolo. Mais de 170 fatores atuam de forma transitória no processamento dos precursores para gerar os rRNAs maduros que formarão as subunidades ribossomais no citoplasma. Entre as proteínas envolvidas na síntese de ribossomos está a Nip7p, uma proteína nucleolar de 21 kDa associada ao complexo pré-60S em Saccharomyces cerevisiae. Nip7p é conservada e possui ortólogas em eucariotos e em Archaea. A análise da seqüência primária revela a presença de um domínio conservado na região C-terminal, denominado PUA, encontrado em diversas proteínas associadas a modificações no RNA. Neste trabalho, foram realizadas análises estruturais e funcionais com o objetivo de investigar a função molecular da proteína Nip7 no processamento e modificação do rRNA. A estrutura tri-dimensional de PaNip7, ortóloga de Nip7p em Pyrococcus abyssi foi resolvida por difração de raios-X até 1,8Å de resolução, utilizando o método SIRAS. Comparação estrutural seguida por ensaios in vitro confirmaram o envolvimento do domínio PUA na interação com RNA. Além disso, tanto Nip7p como suas ortólogas PaNip7 e HsNip7 interagem com seqüências ricas em uridina, indicando que atuam de forma semelhante no processamento do rRNA. Essa preferência por uridina pode ainda explicar a afinidade da proteína Nip7p de S. cerevisiae pelo RNA da região ITS2, conforme observado em ensaios de interação utilizando UV-crosslinking. De fato, uma análise funcional realizada por primer extension comprovou que ocorre um bloqueio no processamento da região espaçadora ITS2 na ausência de Nip7p. Nip7p interage com várias proteínas do complexo pré-60S, entre as quais Nop8p e Nop53p, ambas associadas ao processamento do pré-27S. Embora os ensaios de co-purificação tenham confirmado a interação com as proteínas do complexo H/ACA box, deficiência em Nip7p não afeta a pseudo-uridinilação do rRNA. O duplo-híbrido realizado com a ortóloga humana de Nip7p, HsNip7, revelou interações com FTSJ3 e com a proteína SUMO-2. A interação direta de HsNip7 com estas proteínas foi confirmada por ensaios in vitro. HsNip7 e FTSJ3 colocalizaram na região nucleolar de células HEK293. FTSJ3 é uma proteína não caracterizada que possui o domínio FtsJ, descrito inicialmente para rRNA metiltransferases de procariotos. Além disso, FTSJ3 apresenta similaridade de sequência à proteína Spb1p de levedura, cuja função na metilação do rRNA 25S na posição Gm2922 já foi estabelecida. Embora a Nip7p não interaja com a Spb1p, estes dados indicam que FTSJ3 deve ser a ortóloga humana da Spb1p. As proteínas SUMO estão envolvidas na modificação pós-traducional (sumoylation) que regula a localização subcelular de proteínas. Em levedura, a provável ortóloga de SUMO, Smt3p, foi descrita na partícula pré-60S, portanto a interação HsNip7-SUMO-2 pode ser específica. Estes dados sugerem que as proteínas atuem no mesmo complexo da formação da subunidade 60S também em células humanas / Abstract: Ribosome biogenesis is conserved throughout eukaryotes and takes place in the nucleolus, a specialized nuclear compartment where the rRNA precursors are transcribed. More than 170 trans-acting factors coordinately interact to generate the mature rRNAs. Among the proteins identified in the pre-60S particle in Saccharomyces cerevisiae is Nip7p. Highly conserved Nip7p orthologues are found in all eukaryotes and Archaea. The analysis of Nip7p sequence reveals a conserved C-terminal domain named PUA, also found in a number of RNA-interacting proteins. In this work, we performed structural and functional analysis to investigate Nip7p molecular role on rRNA processing and modification. The structure of Pyrococcus abyssi Nip7p ortholog, PaNip7, was solved using X-ray diffraction data to 1,8Å resolution. Structural analysis followed by in vitro assays confirmed the involvement of PUA domain in RNA interaction. S. cerevisiae Nip7p and its archaeal and human counterparts show preference for binding uridine-rich sequences, indicating conserved functional features among the orthologues. The preference for uridine can explain the higher affinity of S. cerevisiae Nip7p for ITS2 sequence, as observed by UV-crosslinking assays. Consistently, functional analysis revealed pre-rRNA processing in the ITS2 region is seriously impaired. Yeast two-hybrid analysis confirmed by pull down assays revealed Nip7p interacts with Nop8p and Nop53p, two nucleolar proteins involved in pre-27S processing and components of pre-60S particle. Although yeast two-hybrid and pull down assays indicated that Nip7p interacts with H/ACA box core proteins, pseudouridylation is not affected under conditions of Nip7p depletion. In addition, yeast two-hybrid analysis confirmed by GST-pull down revealed HsNip7 interaction with FTSJ3 and SUMO-2. Both HsNip7 and FTSJ3 showed nucleolar subcellular localization in HEK293 cells. FTSJ3 is an uncharacterized protein containing the FtsJ domain, initially described in prokaryotic rRNA methyl-transferases. FTSJ3 shows sequence similarity to yeast Spb1p, an rRNA methyl-transferase involved in methylation of Gm2922, indicating that FTSJ3 may be the human orthologue of Spb1p. Sumoylation is a post-transcriptional covalent modification involved in regulation of protein subcellular localization. Putative yeast orthologues of SUMO, such as Smt3p, have been described in the pre-60S ribosomal particle, suggesting that SUMO-2 might play a specific role in 60S subunit biogenesis / Doutorado / Genetica Animal e Evolução / Doutor em Genetica e Biologia Molecular
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A Genetic Approach to Identify Proteins that Interact with Eukaryotic Microtubule Severing Proteins via a Yeast Two Hybrid SystemAlhassan, Hassan H 05 1900 (has links)
Microtubules (MT) are regulated by multiple categories of proteins, including proteins responsible for severing MTs that are therefore called MT-severing proteins. Studies of katanin, spastin, and fidgetin in animal systems have clarified that these proteins are MT-severing. However, studies in plants have been limited to katanin p60, and little is known about spastin or fidgetin and their function in plants. I looked at plant genomes to identify MT-severing protein homologues to clarify which severing proteins exist in plants. I obtained data from a variety of eukaryotic species to look for MT-severing proteins using homology to human proteins and analyzed these protein sequences to obtain information on the evolution of MT-severing proteins in different species. I focused this analysis on MT-severing proteins in the maize and Arabidopsis thaliana genomes. I created evolutionary phylogenetic trees for katanin-p60, katanin-p80, spastin, and fidgetin using sequences from animal, plant, and fungal genomes. I focused on Arabidopsis spastin and worked to understand its functionality by identifying protein interaction partners. The yeast two-hybrid technique was used to screen an Arabidopsis cDNA library to identify putative spastin interactors. I sought to confirm the putative protein interactions by using molecular tools for protein localization such as the YFP system. Finally, a Biomolecular Fluorescence Complementation (BiFC) assay was initiated as a proof of concept for confirmation of in vivo protein-protein interaction.
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Mechanismus und Regulation der subzellulären Lokalisation von Saccharose-SynthaseHoltgräwe, Daniela L. 31 October 2005 (has links)
Die vorliegende Arbeit beschäftigt sich mit verschiedenen Aspekten der Assoziation von Saccharose-Synthase (SUS) mit subzellulären Strukturen. Durch cDNA-Durchmusterungen konnten proteinogene Bindepartner von SUS sowie Aktin identifiziert und zum Teil verifiziert werden. Die dritte Isoform SuS3 aus Mais wurde auf molekularer Ebene identifiziert und das rekombinante Protein biochemisch charakterisiert. Trotz signifikanter Sequenzunterschiede zwischen den SUS-Isoformen, wurden ähnliche katalytische Eigenschaften und mögliche posttranslationale Modifikationen der Enzyme nachgewiesen, darunter die Redox-Modifikation der Enzymaktivität und das Potential zur reversiblen Phosphorylierung. Der Einfluss der Phoshorylierung von SUS auf dessen enzymatische und assoziative Aktivität wurde mittels mutagenisiertem Protein untersucht und zeigte kein stark verändertes Verhalten infolge der Mutationen. Eine metabolische Regulation der SUS-Aktin-Wechselwirkung durch Zucker konnte bestätigt und die katalytische Aktivität von SUS in Gegenwart von Aktin gezeigt werden. Assoziationsstudien von Aktin mit synthetischen Peptiden sowie immunologische Untersuchungen lieferten Hinweise für die Aktinbindedomäne in SUS. Co-Pelletierungsexperimente zeigten die Assoziation von SUS mit Mikrotubuli aus Rinderhirn. In vitro konkurriert SUS mit Aldolase um die Bindung an Miktotubuli. Als proteinogene Bindepartner von SUS wurden einige im Kohlenhydratstoffwechsel sowie im 26S-Proteasom-Komplex involvierte Proteine identifiziert. Ebenso wurde eine Glutathion-Peroxidase identifiziert, die ubiquitäre Transkriptakkumulation dokumentiert und die katalytische Aktivität des rekombinanten Proteins gezeigt. Eine weitere cDNA-Durchmusterung führte zur Identifikation verschiedener glykolytischer Enzyme als potentielle Interaktionspartner von Mais-Aktin sowie zu Bindepartnern, die nach Sequenzanalyse Domänen mit Homologien zu bekannten ABPs aus tierischen Organismen zeigten.
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