Global ETD Search

1	CarcinoEmbryonic Antigen-related Cell Adhesion Molecule 8 (CEACAM8) : Purification, Characterization, Cellular and Clinical Studies Zhao, Linshu January 2004 (has links) <p>A 95-kDa protein was purified from normal human granulocytes. The protein reacted with a monoclonal antibody against CEACAM8. MALDI-Tof and MS/MS analyses revealed the protein to be a CGM6 gene product. Thus, the protein was proved to be identical to CEACAM8. </p><p>An ELISA for CEACAM8 was developed with detection range of 1-64μg/L. Data are presented on the levels of CEACAM8 in the blood of healthy individuals and patients undergoing surgery, as well as in patients with acute infection. The highly elevated levels of CEACAM8 in the blood of these patients were significantly correlated with the surface expression of CEACAM8 on neutrophils and the number of circulating neutrophils, which suggests that CEACAM8 could serve as a biological marker for granulocyte activitiy in vivo. </p><p>The cellular content of CEACAM8 in neutrophils was estimated to be 82.4 ± 8.9 ng/10<sup>6</sup> cells. Subcellular localisation and mobilisation studies showed that the majority of CEACAM8 is present in the secondary granules of human neutrophils, with a small amount on the plasma membranes. Upon stimulation, CEACAM8 translocated to the plasma membranes from the secondary granules and was also released extracellularly (5.5 ± 0.7% of the total content of CEACAM8).</p><p>In eosinophils, the cellular content of CEACAM8 was estimated to be 73.8 ± 6.0 ng/10<sup>6</sup> cells. In these cells, CEACAM8 is mainly stored in secretory vesicles. Upon activation, eosinophils released 5.1 ± 1.1% of the total content of CEACAM8. </p><p>Administration of granulocyte colony-stimulating factor (G-CSF) to healthy individuals resulted in an increased content of CEACAM8 in neutrophils on day 1, and decreased on day 4. However, the content of CEACAM8 in light membrane fractions was increased on day 4. The translocation of CEACAM8 observed <i>in vivo</i> after G-CSF administration is probably not directly related to this cytokine but to other cytokines such as TNF-a. </p> Biochemistry human neutrophil human eosinophil granule proteins CEA CEACAM8 G-CSF ELISA subcellular fractionation Biokemi Biochemistry Biokemi
2	Mechanisms of granule protein mobiliation in blood eosinophils Karawajczyk, Malgorzata January 2000 (has links) <p>Serum levels of eosinophil granule proteins namely ECP, EPO and EPX, which are stored in the matrix of specific granules, were shown to correlate with the course of disease in disorders involving eosinophils. The concentration of eosinophil proteins in serum is the result of their release <i>in vivo</i> and <i>ex vivo</i> during the sampling procedure. Generally, eosinophils release the content of their specific granules in three ways: exocytosis, piecemeal degranulation (PM) or cytolysis. Which of them is operating in circulating eosinophils has not yet been defined. The aim of this thesis was to study the mechanisms of granule protein release from blood eosinophils in respect of protein subcellular localization and cell ultrastructure.</p><p>In patients with bacterial infections, serum levels of ECP but not EPO increased, while in patients with viral infections both proteins remained within the range of healthy controls. G-CSF is a cytokine involved in the response mechanism to bacterial but not viral infections. Administration of G-CSF to healthy subjects induced an elevation of eosinophil numbers and a preferential increase of serum EPX and ECP in comparison to EPO.</p><p>The model of PM consists of the stepwise transportation of specific granule contents from the granules towards the plasma membrane. We observed that administration of G-CSF to healthy subjects and the allergen exposure of allergic subjects during the pollen season, caused changes in the ultrastructure of eosinophil specific granules such as loosening of the matrix, granule matrix lucency and ragged losses of their core. Similar alterations of morphology had been previously described for eosinophils undergoing PM.</p><p>ECP, EPX and EPO were localized not only in the specific granules but also in extra-granular compartments as shown both by immuno electron microscopy and subcelular fractionations, An extra-granular EPX compartment was present in healthy as well as in allergic and in hypereosinophilic subjects, and there were no significant differences in its size between the groups. The size of the extra-granular compartments of ECP and EPO was increased in allergics during the season, and these compartments were clearly separate from that of EPX. Results of this show the differential mobilization ofgranule proteins in blood stream eosinophils serum and indicates PM as its mechanism.</p> Medical sciences eosinophil granule proteins ECP EPX EPO serum levels piecemeal degranulation release ultrastructure subcellular fractionation MEDICIN OCH VÅRD MEDICINE MEDICIN
3	Mechanisms of granule protein mobiliation in blood eosinophils Karawajczyk, Malgorzata January 2000 (has links) Serum levels of eosinophil granule proteins namely ECP, EPO and EPX, which are stored in the matrix of specific granules, were shown to correlate with the course of disease in disorders involving eosinophils. The concentration of eosinophil proteins in serum is the result of their release in vivo and ex vivo during the sampling procedure. Generally, eosinophils release the content of their specific granules in three ways: exocytosis, piecemeal degranulation (PM) or cytolysis. Which of them is operating in circulating eosinophils has not yet been defined. The aim of this thesis was to study the mechanisms of granule protein release from blood eosinophils in respect of protein subcellular localization and cell ultrastructure. In patients with bacterial infections, serum levels of ECP but not EPO increased, while in patients with viral infections both proteins remained within the range of healthy controls. G-CSF is a cytokine involved in the response mechanism to bacterial but not viral infections. Administration of G-CSF to healthy subjects induced an elevation of eosinophil numbers and a preferential increase of serum EPX and ECP in comparison to EPO. The model of PM consists of the stepwise transportation of specific granule contents from the granules towards the plasma membrane. We observed that administration of G-CSF to healthy subjects and the allergen exposure of allergic subjects during the pollen season, caused changes in the ultrastructure of eosinophil specific granules such as loosening of the matrix, granule matrix lucency and ragged losses of their core. Similar alterations of morphology had been previously described for eosinophils undergoing PM. ECP, EPX and EPO were localized not only in the specific granules but also in extra-granular compartments as shown both by immuno electron microscopy and subcelular fractionations, An extra-granular EPX compartment was present in healthy as well as in allergic and in hypereosinophilic subjects, and there were no significant differences in its size between the groups. The size of the extra-granular compartments of ECP and EPO was increased in allergics during the season, and these compartments were clearly separate from that of EPX. Results of this show the differential mobilization ofgranule proteins in blood stream eosinophils serum and indicates PM as its mechanism. Medical sciences eosinophil granule proteins ECP EPX EPO serum levels piecemeal degranulation release ultrastructure subcellular fractionation MEDICIN OCH VÅRD MEDICINE MEDICIN
4	CarcinoEmbryonic Antigen-related Cell Adhesion Molecule 8 (CEACAM8) : Purification, Characterization, Cellular and Clinical Studies Zhao, Linshu January 2004 (has links) A 95-kDa protein was purified from normal human granulocytes. The protein reacted with a monoclonal antibody against CEACAM8. MALDI-Tof and MS/MS analyses revealed the protein to be a CGM6 gene product. Thus, the protein was proved to be identical to CEACAM8. An ELISA for CEACAM8 was developed with detection range of 1-64μg/L. Data are presented on the levels of CEACAM8 in the blood of healthy individuals and patients undergoing surgery, as well as in patients with acute infection. The highly elevated levels of CEACAM8 in the blood of these patients were significantly correlated with the surface expression of CEACAM8 on neutrophils and the number of circulating neutrophils, which suggests that CEACAM8 could serve as a biological marker for granulocyte activitiy in vivo. The cellular content of CEACAM8 in neutrophils was estimated to be 82.4 ± 8.9 ng/106 cells. Subcellular localisation and mobilisation studies showed that the majority of CEACAM8 is present in the secondary granules of human neutrophils, with a small amount on the plasma membranes. Upon stimulation, CEACAM8 translocated to the plasma membranes from the secondary granules and was also released extracellularly (5.5 ± 0.7% of the total content of CEACAM8). In eosinophils, the cellular content of CEACAM8 was estimated to be 73.8 ± 6.0 ng/106 cells. In these cells, CEACAM8 is mainly stored in secretory vesicles. Upon activation, eosinophils released 5.1 ± 1.1% of the total content of CEACAM8. Administration of granulocyte colony-stimulating factor (G-CSF) to healthy individuals resulted in an increased content of CEACAM8 in neutrophils on day 1, and decreased on day 4. However, the content of CEACAM8 in light membrane fractions was increased on day 4. The translocation of CEACAM8 observed in vivo after G-CSF administration is probably not directly related to this cytokine but to other cytokines such as TNF-a. Biochemistry human neutrophil human eosinophil granule proteins CEA CEACAM8 G-CSF ELISA subcellular fractionation Biokemi Biochemistry Biokemi
5	Toxicité, transfert et gestion subcellulaire de l’yttrium (Y) chez trois organismes d’eau douce Cardon, Pierre-Yves 11 1900 (has links) No description available. Terres rares fractionnement subcellulaire écotoxicologie eau douce transfert trophique Rare earth Yttrium Ecotoxicology Bioassays Trophic transfer Subcellular fractionation Daphnia magna Chironomus riparius Oncorhynchus mykiss
6	Identification of subcellular compartments containing disseminated α-synuclein seeds by proteomic analysis / プロテオミクス解析による伝播したアルファシヌクレインシードを有する細胞内構成物の同定 / プロテオミクスカイセキニヨルデンパシタアルファシヌクレインシードオユウスルサイボウナイコウセイブツノドウテイ笠原潤也, Junya Kasahara 22 March 2021 (has links) 博士(理学) / Doctor of Philosophy in Science / 同志社大学 / Doshisha University 既形成原線維量子ドット迅速な拡散シナプス細胞亜分画 Pre-formed fibril Quantum dot Rapid dissemination Synapse Fluorescence-activated organelle sorting Subcellular fractionation
7	Development of Fluorescence Activated Synaptosome Sorting (FASS) and analysis of VGLUT1 synapses from mouse brain / Entwicklung von „Fluorescence Activated Synaptosome Sorting“ (FASS) und die Analyse von VGLUT1-Synapsen des Mäusehirns Biesemann, Christoph 11 November 2010 (has links) No description available. 570 Biowissenschaften Biologie WXG 900 WF 850 WHC 700 Vesikulärer Glutamattransporter VGLUT FASS FACS Durchflusszytometrie Synaptosom Proteom Subzelluläre Fraktionierung Synapse FXYD6 Tpd52 Vesicular Glutamate Transporter VGLUT FASS FACS flow cytometry synaptosome proteomics subcellular fractionation synapse FXYD6 Tpd52 42.63 42.15
8	Caractérisation systématique des motifs de régulation en cis à l’échelle transcriptomique et liens avec la localisation des ARN Benoit Bouvrette, Louis Philip 04 1900 (has links) La localisation subcellulaire de l’ARN permet un déploiement prompt et spatialement restreint autant des activités protéiques que des ARN noncodant. Le trafic d’ARN est dirigé par des éléments de séquences (sous-séquences primaires, structures secondaires), aussi appelés motifs de régulation, présents en cis à même la molécule d’ARN. Ces motifs sont reconnus par des protéines de liaisons aux ARN qui médient l’acheminement des transcrits vers des sites précis dans la cellule. Des études récentes, chez l’embryon de Drosophile, indiquent que la majorité des ARN ont une localisation subcellulaire asymétrique, suggérant l’existence d’un « code de localisation » complexe. Cependant, ceci peut représenter un exemple exceptionnel et la question demeurait, jusqu’ici, si une prévalence comparable de localisation d’ARN est observable chez des cellules standards développées en culture. De plus, des informations facilement disponibles à propos des caractéristiques de distribution topologique d’instances de motifs à travers des transcriptomes complets étaient jusqu’à présent manquantes. Afin d’avoir un aperçu de l’étendue et des propriétés impliquées dans la localisation des ARN, nous avons soumis des cellules de Drosophile (D17) et de l’humain (HepG2) à un fractionnement biochimique afin d’isoler les fractions nucléaire, cytosolique, membranaire et insoluble. Nous avons ensuite séquencé en profondeur l’ARN extrait et analysé par spectrométrie de masse les protéines extraites de ces fractions. Nous avons nommé cette méthode CeFra-Seq. Par des analyses bio-informatiques, j’ai ensuite cartographié l’enrichissement de divers biotypes d’ARN (p. ex. ARN messager, ARN long non codant, ARN circulaire) et protéines au sein des fractions subcellulaires. Ceci a révélé que la distribution d’un large éventail d’espèces d’ARN codants et non codants est asymétrique. Une analyse des gènes orthologues entre mouche et humain a aussi démontré de fortes similitudes, suggérant que le processus de localisation est évolutivement conservé. De plus, j’ai observé des attributs (p. ex. la taille des transcrits) distincts parmi les populations d’ARN messagers spécifiques à une fraction. Finalement, j’ai observé des corrélations et anti-corrélations spécifiques entre certains groupes d’ARN messagers et leurs protéines. Pour permettre l’étude de la topologie de motifs et de leurs conservations, j’ai créé oRNAment, une base de données d’instances présumée de sites de liaison de protéines chez des ARN codants et non codants. À partir de données de motifs de liaison protéique par RNAcompete et par RNA Bind-n-Seq, j’ai développé un algorithme permettant l’identification rapide d’instances potentielles de ces motifs dans un transcriptome complet. J’ai pu ainsi cataloguer les instances de 453 motifs provenant de 223 protéines liant l’ARN pour 525 718 transcrits chez cinq espèces. Les résultats obtenus ont été validés en les comparant à des données publiques de eCLIP. J’ai, par la suite, utilisé oRNAment pour analyser en détail les aspects topologiques des instances présumées de ces motifs et leurs conservations évolutives relatives. Ceci a permis de démontrer que la plupart des motifs sont distribués de façon similaire entre espèces. De plus, j’ai discerné des points communs entre les sous-groupes de protéines liant des biotypes distincts ou des régions d’ARN spécifiques. La présence de tels patrons, similaires ou non, entre espèces est susceptible de refléter l’importance de leurs fonctions. D’ailleurs, l’analyse plus détaillée du positionnement d’un motif entre régions transcriptomiques comparables chez les vertébrés suggère une conservation synténique de ceux-ci, à divers degrés, pour tous les biotypes d’ARN. La topologie régionale de certaines instances de motifs répétées apparaît aussi comme évolutivement conservée et peut être importante afin de permettre une liaison adéquate de la protéine. Finalement, les résultats compilés avec oRNAment ont permis de postuler sur un nouveau rôle potentiel pour l’ARN long non codant HELLPAR comme éponge de protéines liant l’ARN. La caractérisation systématique d’ARN localisés et de motifs de régulation en cis présentée dans cette thèse démontre comment l’intégration d’information à l’échelle transcriptomique permet d’évaluer la prévalence de l’asymétrie, les caractéristiques distinctes et la conservation évolutive de collections d’ARN. / The subcellular localization of RNA allows a rapid and spatially restricted deployment of protein and noncoding RNA activities. The trafficking of RNA is directed by sequence elements (primary subsequences, secondary structures), also called regulatory motifs, present in cis within the RNA molecule. These motifs are recognized by RNA-binding proteins that mediate the transport of transcripts to specific sites in the cell. Recent studies in the Drosophila embryo indicate that the majority of RNAs display an asymmetric subcellular localization, suggesting the existence of a complex "localization code". However, this may represent an exceptional example and the question remained, until now, whether a comparable prevalence of RNA localization is observable in standard cells grown in culture. In addition, readily available information about the topological distribution of pattern instances across full transcriptomes has been hitherto lacking. In order to have a broad overview of the extent and properties involved in RNA localization, we subjected Drosophila (D17) and human (HepG2) cells to biochemical fractionation to isolate the nuclear, cytosolic, membrane and insoluble fractions. We then performed deep sequencing on the extracted RNA and analyzed through mass spectrometry the proteins extracted from these fractions. We named this method CeFra-Seq. Through bioinformatics analyses, I then profiled the enrichment of various RNA biotypes (e.g. messenger RNA, long noncoding RNA, circular RNA) and proteins within the subcellular fractions. This revealed the high prevalence of asymmetric distribution of both coding and noncoding RNA species. An analysis of orthologous genes between fly and human has also shown strong similarities, suggesting that the localization process is evolutionarily conserved. In addition, I have observed distinct attributes (e.g. transcript size) among fraction-specific messenger RNA populations. Finally, I observed specific correlations and anti-correlations between defined groups of messenger RNAs and the proteins they encode. To study motifs topology and their conservation, I created oRNAment, a database of putative RNA-binding protein binding sites instances in coding and noncoding RNAs. Using data from protein binding motifs assessed by RNAcompete and by RNA Bind-n-Seq experiments, I have developed an algorithm allowing their rapid identification in a complete transcriptome. I was able to catalog the instances of 453 motifs from 223 RNA-binding proteins for 525,718 transcripts in five species. The results obtained were validated by comparing them with public data from eCLIP. I then used oRNAment to further analyze the topological aspects of these motifs’ instances and their relative evolutionary conservation. This showed that most motifs are distributed in a similar fashion between species. In addition, I have detected commonalities between the subgroups of proteins linking preferentially distinct biotypes or specific RNA regions. The presence or absence of such pattern between species is likely a reflection of the importance of their functions. Moreover, a more precise analysis of the position of a motif among comparable transcriptomic regions in vertebrates suggests a syntenic conservation, to varying degrees, in all RNA biotypes. The regional topology of certain motifs as repeated instances also appears to be evolutionarily conserved and may be important in order to allow adequate binding of the protein. Finally, the results compiled with oRNAment allowed to postulate on a potential new role for the long noncoding RNA HELLPAR as an RNA-binding protein sponge. The systematic characterization of RNA localization and cis regulatory motifs presented in this thesis demonstrates how the integration of information at a transcriptomic scale enables the assessment of the prevalence of asymmetry, the distinct characteristics and the evolutionary conservation of RNA clusters. Localisation de l’ARN Régulation post-transcriptionnelle Transcriptomique ARN messagers ARN non codants Protéine liant l’ARN Motifs de régulation en cis Fractionnement subcellulaire Séquençage en profondeur de l’ARN Conservation évolutive RNA localization Post-transcriptional regulation Transcriptomics Messenger RNA Noncoding RNA RNA binding protein Cis-regulatory motifs Subcellular fractionation RNA-sequencing Evolutionary conservation

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