Global ETD Search

1	Class II MHC function in macrophages and mice infected with mycobacterium Nepal, Rajeev Mani 15 March 2006 (has links) No description available. Class II MHC Mycobacteria Mycobacterium tuberculosis Mycobacterium avium Cathepsin Cathepsin L DM Macrophage GMCSF M-CSF Stability Class II MHC
2	The MHC-glycopeptide-T cell interaction in collagen induced arthritis : a study using glycopeptides, isosteres and statistical molecular design in a mouse model for rheumatoid arthritis Holm, Lotta January 2006 (has links) <p>Rheumatoid arthritis (RA) is an autoimmune disease affecting approximately 1% of the population in the western world. It is characterised by a tissue specific attack of cartilage in peripheral joints. Collagen induced arthritis (CIA) is one of the most commonly used animal models for (RA), with similar symptoms and histopathology. CIA is induced by immunisation of mice with type II collagen (CII), and the immunodominant part was previously found to be located between residues 256-270. This thesis describes the interaction between the MHC molecule, glycopeptide antigens from CII and the T cells that is essential in development of CIA. The glycopeptide properties for binding to the mouse MHC molecule Aq have been studied, as well as interaction points in the glycopeptide that are critical for stimulation of a T-cell response.</p><p>The thesis is based on five studies. In the first paper the minimal glycopeptide core, that is required for binding to the Aq molecule while still giving a full T cell response was determined. The second paper studied the roles of amino acid side-chains and a backbone amide bond as T-cell contact points. In the third paper the hydrogen bond donor-acceptor characteristics of the 4-OH galactose hydroxyl group of the glycopeptide was studied in detail. In the fourth paper we established a structure activity relationship (QSAR model) for (glyco)peptide binding to the Aq molecule. Finally, the stereochemical requirements for glycopeptide binding to the Aq molecule and for T-cell recognition was studied in the fifth paper.</p><p>The study was performed using collagen glycopeptide analogues, which were synthesised on solid phase. Amide bond and hydroxyl group isosteres were introduced for study of hydrogen bond donor-acceptor characteristics. Statistical methods were used to design a representative peptide test set and in establishing a QSAR model.</p><p>The results give a deeper understanding of the interactions involved in the ternary MHC-glycopeptide-T cell complex. This information contributes to research directed towards finding new treatments for RA.</p> Rheumatoid arthritis collagen T-cell class II MHC solid phase peptide synthesis glycopeptide peptide isostere PCA statistical molecular design PLS QSAR sequence binding motif Organic chemistry Organisk kemi
3	The MHC-glycopeptide-T cell interaction in collagen induced arthritis : a study using glycopeptides, isosteres and statistical molecular design in a mouse model for rheumatoid arthritis Holm, Lotta January 2006 (has links) Rheumatoid arthritis (RA) is an autoimmune disease affecting approximately 1% of the population in the western world. It is characterised by a tissue specific attack of cartilage in peripheral joints. Collagen induced arthritis (CIA) is one of the most commonly used animal models for (RA), with similar symptoms and histopathology. CIA is induced by immunisation of mice with type II collagen (CII), and the immunodominant part was previously found to be located between residues 256-270. This thesis describes the interaction between the MHC molecule, glycopeptide antigens from CII and the T cells that is essential in development of CIA. The glycopeptide properties for binding to the mouse MHC molecule Aq have been studied, as well as interaction points in the glycopeptide that are critical for stimulation of a T-cell response. The thesis is based on five studies. In the first paper the minimal glycopeptide core, that is required for binding to the Aq molecule while still giving a full T cell response was determined. The second paper studied the roles of amino acid side-chains and a backbone amide bond as T-cell contact points. In the third paper the hydrogen bond donor-acceptor characteristics of the 4-OH galactose hydroxyl group of the glycopeptide was studied in detail. In the fourth paper we established a structure activity relationship (QSAR model) for (glyco)peptide binding to the Aq molecule. Finally, the stereochemical requirements for glycopeptide binding to the Aq molecule and for T-cell recognition was studied in the fifth paper. The study was performed using collagen glycopeptide analogues, which were synthesised on solid phase. Amide bond and hydroxyl group isosteres were introduced for study of hydrogen bond donor-acceptor characteristics. Statistical methods were used to design a representative peptide test set and in establishing a QSAR model. The results give a deeper understanding of the interactions involved in the ternary MHC-glycopeptide-T cell complex. This information contributes to research directed towards finding new treatments for RA. Rheumatoid arthritis collagen T-cell class II MHC solid phase peptide synthesis glycopeptide peptide isostere PCA statistical molecular design PLS QSAR sequence binding motif Organic chemistry Organisk kemi
4	Régulation des chaperons de la présentation antigénique par ubiquitination Ladouceur, Annie 05 1900 (has links) La chaîne invariante forme un complexe nonamérique avec les molécules classiques du CMH de classe II. HLA-DM et HLA-DO, des molécules non-classiques de classe II, sont aussi impliquées dans la présentation des peptides antigéniques aux lymphocytes T. Ces molécules chaperones de la présentation antigénique modulent la capacité d’une cellule à présenter des antigènes par les moloécules classiques du CMH de classe II. La régulation transcriptionnelle des molécules chaperones, tout comme celle des autres molécules du CMH de classe II, est assurée par le transactivateur CIITA. La molécule HLA-DR peut être régulée négativement de manière post-traductionnelle par ubiquitination grâce à l’enzyme E3 ubiquitine ligase MARCH1. Celle-ci est induite par l’interleukine-10 dans les monocytes. L’objectif de ce projet était de déterminer si l’ubiquitination par MARCH1 peut aussi réguler l’expression des molécules chaperones de la présentation antigénique. Les expériences furent réalisées dans le contexte de co-transfections en cellules HEK293T. L’expression des molécules fut évaluée par immunomarquages et cytométrie de flux. Il a été montré que l’isoforme p33 de la chaîne invariante est régulé négativement en présence de MARCH1 à partir de la surface cellulaire, causant ainsi sa dégradation. Tel que démontré par l’utilisation d’un mutant dépourvu de queue cytoplasmique, cette dernière région n’est pas indispensable à ce phénomène. Une hypothèse est qu’une molécule non-identifiée, associée à Ii, serait ubiquitinée par MARCH1, l’entraînant dans sa régulation négative. Il fut déterminer que cette molécule n’était pas CXCR2, un récepteur pouvant être impliqué, avec la chaîne invariante et CD44, en tant que récepteur de MIF (Macrophage Inhibitory Factor). Il fut aussi montré que HLA-DO peut être ciblé par MARCH1 mais ceci ne semble pas être un phénomène dominant; l’expression des complexes DO/DM n’étant pas affectée bien qu’ils entrent en interaction avec MARCH1. L’expression de HLA-DM n’est pas affectée par MARCH1. Il n’a toutefois pas été déterminé hors de tout doute si MARCH1 peut modifier DM; des résultats obtenus avec une queue cytoplasmique de DM possédant une lysine laissant suggérer qu’il est possible que MARCH1 interagisse avec DM. Dans l’ensemble, les travaux démontrent que l’ubiquitination par MARCH1 joue un rôle dans la régulation post-transcriptionnelle de la chaîne invariante p33 mais pas HLA-DO et HLA-DM. / The invariant chain, which form a nonameric complex with the classical MHC class II molecules. HLA-DM and HLA-DO (non-classical class II molecules) are involved in the presentation of antigens to T lymphocytes. The chaperons molecules of the antigenic presentation can modulate the capacity of the cells to present antigens. The transcriptional regulation of the chaperons and all of the other molecules linked to the MHC is assured by the CIITA transactivator. Little is know of the post-transcriptional mechanisms, other than the fact that HLA-DR molecule can be down-regulated by ubiquitination due to E3 ubiquitin ligase MARCH1. MARCH1 is induce by interleukin-10 in monocytes. The goal of this project is to figure out if ubiquitination by MARCH1 can also regulate the expression of the antigenic presentation chaperons. The experiences were performed in the context of co-transfections in HEK293T cells and the expression of the diverses molecules was evaluated by cell stainings and FACS analysis. The p33 isoform of the invariant chain was found to be down-regulated and degraded in the presence of MARCH1. The invariant chain cytoplasmic tail is not completely essential to this phenomenon; a non-identified molecule, associated with Ii, is probably ubiquitinated by MARCH1 and is then down-regulated, together with Ii. It was shown tha CXCR2, a reeptor involved with the invariant chain and CD44 in the reception of the MIF signal, is not that molecule. HLA-DO can ben targetd by MARCH1 but this does not seem to be a general phenomenon; the expression of the DO/DM complexes remaning unaffected even with the interaction of those complexes with MARCH1. Therefore, a certain protection seem to be provided by HLA-DM to HLA-DO. The expression of HLA-DM itself is not affected by the presence of MARCH1. However, it was not cleary demonstrated if MARCH1 can modify DM. Some results obtained with a cytoplasmic tail of DM comprising an additional lysine suggest that there is a possibility that MARCH1 interact with DM. Generally, the work presented here show that ubiquitination by MARCH1 is involved in post-transcriptionnal regulation of the p33 isoform of the invariant chain but not in the regulation of HLA-DO and HLA-DM. Chaîne invariante (Ii) Molécules non-classiques de classe II HLA-DM HLA-DO E3 ubiquitine ligase MARCH1 MARCH HLA Invariant chain (Ii) Non-classical class II molecules Classical class II MHC molecules
5	Charakterizace imunitního systém s využitím MHC II/ EGFP knock-in myši / Studying immune system using MHC II/ EGFP knock-in mouse Zadražil, Zdeněk January 2012 (has links) The immune system is essential for keeping the integrity of multicellular organisms. We were able to make a step forward in studying the complex immune reactions in mammals in vivo and/ or in situ using the major histocompatibility complex (MHC) class II/ enhanced green fluorescent protein (EGFP) knock-in mouse model. Due to the EGFP visualization of MHC II expressing cells we were able to observe antigen presenting cells, which are essential for the onset of immune responses, in their natural environment. Thus, we report some original features of the immune system. We have identified MHC II+ cell clusters with unknown, probably unique function, in the intestine. We have also described MHC II+ cell migration to the lactating mammary gland and tested few hypotheses about the role of this phenomenon for the development of the mammary gland, milk secretion or infant immune system establishment. Lastly, we observed residential macrophages in the cornea. The presence of APCs in the cornea is a very contradictory issue due to the fact that cornea is an immunologically privileged tissue and therefore harbors special immune features. key words: antigen presenting cells (APC), major histocompatibility complex class II (MHC II), enhanced green fluorescent protein (EGFP), immune system, knock-in mouse model
6	Modified Glycopeptides Targeting Rheumatoid Arthritis : Exploring molecular interactions in class II MHC/glycopeptide/T-cell receptor complexes Andersson, Ida E. January 2011 (has links) Rheumatoid arthritis (RA) is an autoimmune inflammatory disease that leads to degradation of cartilage and bone mainly in peripheral joints. In collagen-induced arthritis (CIA), a mouse model for RA, activation of autoimmune CD4+ T cells depends on a molecular recognition system where T-cell receptors (TCRs) recognize a complex between the class II MHC Aq protein and CII259-273, a glycopeptide epitope from type II collagen (CII). Interestingly, vaccination with the Aq/CII259-273 complex can relieve symptoms and cause disease regression in mice. This thesis describes the use of modified glycopeptides to explore interactions important for binding to the Aq protein and recognition by autoimmune T-cell hybridomas obtained from mice with CIA. The CII259-273 glycopeptide was modified by replacement of backbone amides with different amide bond isosteres, as well as substitution of two residues that anchor the glycopeptide in prominent pockets in the Aq binding site. A three-dimensional structure of the Aq/glycopeptide complex was modeled to provide a structural basis for interpretation of the modified glycopeptide’s immunological activities. Overall, it was found that the amide bond isosteres affected Aq binding more than could be explained by the static model of the Aq/glycopeptide complex. Molecular dynamics (MD) simulations, however, revealed that the introduced amide bond isosteres substantially altered the hydrogen-bonding network formed between the N-terminal 259-265 backbone sequence of CII259-273 and Aq. These results indicated that the N-terminal hydrogen-bonding interactions follow a cooperative model, where the strength and presence of individual hydrogen bonds depended on the neighboring interactions. The two important anchor residues Ile260 and Phe263 were investigated using a designed library of CII259-273 based glycopeptides with substitutions by different (non-)natural amino acids at positions 260 and 263. Evaluation of binding to the Aq protein showed that there was scope for improvement in position 263 while Ile was preferred in position 260. The obtained SAR understanding provided a valuable basis for future development of modified glycopeptides with improved Aq binding. Furthermore, the modified glycopeptides elicited varying T-cell responses that generally could be correlated to their ability to bind to Aq. However, in several cases, there was a lack of correlation between Aq binding and T-cell recognition, which indicated that the interactions with the TCRs were determined by other factors, such as presentation of altered epitopes and changes in the kinetics of the TCR’s interaction with the Aq/glycopeptide complex. Several of the modified glycopeptides were also found to bind well to the human RA-associated DR4 protein and elicit strong responses with T-cell hybridomas obtained from transgenic mice expressing DR4 and the human CD4 co-receptor. This encourages future investigations of modified glycopeptides that can be used to further probe the MHC/glycopeptide/TCR recognition system and that also constitute potential therapeutic vaccines for treatment of RA. As a step towards this goal, three modified glycopeptides presented in this thesis have been identified as candidates for vaccination studies using the CIA mouse model. Major histocompatibility complex class II MHC T-cell receptor rheumatoid arthritis collagen-induced arthritis glycopeptide amide bond isostere comparative modeling rational design molecular docking molecular dynamics simulation statistical molecular design Bioorganic chemistry Bioorganisk kemi
7	Régulation des chaperons de la présentation antigénique par ubiquitination Ladouceur, Annie 05 1900 (has links) La chaîne invariante forme un complexe nonamérique avec les molécules classiques du CMH de classe II. HLA-DM et HLA-DO, des molécules non-classiques de classe II, sont aussi impliquées dans la présentation des peptides antigéniques aux lymphocytes T. Ces molécules chaperones de la présentation antigénique modulent la capacité d’une cellule à présenter des antigènes par les moloécules classiques du CMH de classe II. La régulation transcriptionnelle des molécules chaperones, tout comme celle des autres molécules du CMH de classe II, est assurée par le transactivateur CIITA. La molécule HLA-DR peut être régulée négativement de manière post-traductionnelle par ubiquitination grâce à l’enzyme E3 ubiquitine ligase MARCH1. Celle-ci est induite par l’interleukine-10 dans les monocytes. L’objectif de ce projet était de déterminer si l’ubiquitination par MARCH1 peut aussi réguler l’expression des molécules chaperones de la présentation antigénique. Les expériences furent réalisées dans le contexte de co-transfections en cellules HEK293T. L’expression des molécules fut évaluée par immunomarquages et cytométrie de flux. Il a été montré que l’isoforme p33 de la chaîne invariante est régulé négativement en présence de MARCH1 à partir de la surface cellulaire, causant ainsi sa dégradation. Tel que démontré par l’utilisation d’un mutant dépourvu de queue cytoplasmique, cette dernière région n’est pas indispensable à ce phénomène. Une hypothèse est qu’une molécule non-identifiée, associée à Ii, serait ubiquitinée par MARCH1, l’entraînant dans sa régulation négative. Il fut déterminer que cette molécule n’était pas CXCR2, un récepteur pouvant être impliqué, avec la chaîne invariante et CD44, en tant que récepteur de MIF (Macrophage Inhibitory Factor). Il fut aussi montré que HLA-DO peut être ciblé par MARCH1 mais ceci ne semble pas être un phénomène dominant; l’expression des complexes DO/DM n’étant pas affectée bien qu’ils entrent en interaction avec MARCH1. L’expression de HLA-DM n’est pas affectée par MARCH1. Il n’a toutefois pas été déterminé hors de tout doute si MARCH1 peut modifier DM; des résultats obtenus avec une queue cytoplasmique de DM possédant une lysine laissant suggérer qu’il est possible que MARCH1 interagisse avec DM. Dans l’ensemble, les travaux démontrent que l’ubiquitination par MARCH1 joue un rôle dans la régulation post-transcriptionnelle de la chaîne invariante p33 mais pas HLA-DO et HLA-DM. / The invariant chain, which form a nonameric complex with the classical MHC class II molecules. HLA-DM and HLA-DO (non-classical class II molecules) are involved in the presentation of antigens to T lymphocytes. The chaperons molecules of the antigenic presentation can modulate the capacity of the cells to present antigens. The transcriptional regulation of the chaperons and all of the other molecules linked to the MHC is assured by the CIITA transactivator. Little is know of the post-transcriptional mechanisms, other than the fact that HLA-DR molecule can be down-regulated by ubiquitination due to E3 ubiquitin ligase MARCH1. MARCH1 is induce by interleukin-10 in monocytes. The goal of this project is to figure out if ubiquitination by MARCH1 can also regulate the expression of the antigenic presentation chaperons. The experiences were performed in the context of co-transfections in HEK293T cells and the expression of the diverses molecules was evaluated by cell stainings and FACS analysis. The p33 isoform of the invariant chain was found to be down-regulated and degraded in the presence of MARCH1. The invariant chain cytoplasmic tail is not completely essential to this phenomenon; a non-identified molecule, associated with Ii, is probably ubiquitinated by MARCH1 and is then down-regulated, together with Ii. It was shown tha CXCR2, a reeptor involved with the invariant chain and CD44 in the reception of the MIF signal, is not that molecule. HLA-DO can ben targetd by MARCH1 but this does not seem to be a general phenomenon; the expression of the DO/DM complexes remaning unaffected even with the interaction of those complexes with MARCH1. Therefore, a certain protection seem to be provided by HLA-DM to HLA-DO. The expression of HLA-DM itself is not affected by the presence of MARCH1. However, it was not cleary demonstrated if MARCH1 can modify DM. Some results obtained with a cytoplasmic tail of DM comprising an additional lysine suggest that there is a possibility that MARCH1 interact with DM. Generally, the work presented here show that ubiquitination by MARCH1 is involved in post-transcriptionnal regulation of the p33 isoform of the invariant chain but not in the regulation of HLA-DO and HLA-DM. Chaîne invariante (Ii) Molécules non-classiques de classe II HLA-DM HLA-DO E3 ubiquitine ligase MARCH1 MARCH HLA Invariant chain (Ii) Non-classical class II molecules Classical class II MHC molecules
8	Effet de Streptococcus Suis sur la capacité de présentation antigénique de cellules dendritiques Letendre, Corinne 04 1900 (has links) Streptococcus suis est un important pathogène porcin et humain, causant méningites et septicémies. Des études suggèrent que S. suis dispose de facteurs de virulence, notamment sa capsule polysaccharidique (CPS), qui lui permettent de moduler les fonctions des cellules dendritiques (DCs), situées à l’interface entre l’immunité innée et adaptative. Les difficultés à développer un vaccin efficace suggèrent aussi une altération de la voie T dépendante. L’objectif général du projet était d’évaluer l’effet de S. suis sur l’activation des cellules T CD4+ ainsi que sur la capacité de présentation antigénique des DCs. Nous avons étudié dans un modèle murin in vivo la réponse T CD4+ mémoire lors d’infections primaire et secondaire. Une faible réponse mémoire centrale a été obtenue, suggérant que la réponse adaptative générée contre S. suis est limitée. Étant donné l’importance du complexe majeur d’histocompatibilité (MHC) de classe II dans la présentation antigénique, nous avons évalué in vitro et in vivo l’expression de ces molécules chez les DCs. Une modulation de l’expression du MHC-II par S. suis a été observée. L’analyse de la transcription de gènes impliqués dans la régulation transcriptionnelle et post-transcriptionnelle du MHC-II nous permet de suggérer que S. suis régule à la baisse la synthèse de nouvelles molécules et favorise leur dégradation lysosomale. Cette stratégie, dans laquelle la CPS ne jouerait qu’un rôle partiel, permettrait à S. suis d’échapper à la réponse adaptative T dépendante. Les résultats de cette étude fourniront de nouvelles perspectives dans la compréhension de la réponse adaptative lors de l’infection par S. suis. / Streptococcus suis is an important swine and human pathogen causing meningitis and septicemia. Recent studies suggest that S. suis possesses several virulence factors, including the capsular polysaccharide, which enable this pathogen to modulate dendritic cell (DCs) functions. DCs are key immune cells that bridge innate and adaptive immunity. Moreover, the difficulties in developing an effective vaccine suggest that S. suis interferes with the T-cell dependent response. The main objective of the project was to evaluate the effect of S. suis on CD4+ T-cell activation, as well as on the antigen presentation ability of DCs. We investigated the CD4+ T-cell memory response in an in vivo mouse model. A poor central memory response was obtained following primary and secondary infections with S. suis, thus suggesting that the adaptive immune response against this pathogen is limited. The major histocompatibility complex (MHC) class II is central to the antigen presentation pathway. We thus investigated in vitro and in vivo the expression of these molecules on DCs. We observed a modulation in the expression of MHC-II by S. suis. Transcriptional analysis of genes involved in transcriptional and post-transcriptional regulation of MHC-II suggests that S. suis downregulates synthesis of MHC-II molecules and promotes their lysosomal degradation. This strategy, in which the CPS would play only a partial role, might allow S. suis to evade the T-cell dependent adaptive response. Overall, these results provide new insights into the comprehension of the adaptive immune response during the infection by S. suis. Streptococcus suis Cellules dendritiques Lymphocytes T CD4+ Présentation antigénique Réponse mémoire Maturation cellulaire Capsule polysaccharidique Réponse immunitaire adaptative Dendritic cells CD4+ T cells Antigen presentation Memory response Cell maturation Capsular polysaccharides Adaptive immune response

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