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Hematopoese em serpentes Oxyrhopus guibei (Hoge & Romano, 1978) (Ophidia: Dipsadidae): caracterização morfológica, citoquímica e ultraestrutural / Hematopoiesis in Oxyrhopus guibei (Hoge & Romano, 1978) (Ophidia: Dipsadidae) snakes: morphological, cytochemical and ultrastructural characterizationOzzetti, Priscila Aparecida 28 May 2013 (has links)
A hematopoese nas serpentes inicia-se durante a embriogênese e através dos processos de alterações da vida fetal. A primeira atividade eritropoética é extraembrionária, a partir de células mesodérmicas do saco vitelínico e durante o desenvolvimento embrionário torna-se intraembrionário. Em serpentes recém-nascidas e adultas, o principal foco hematopoético ocorre na medula óssea. O objetivo deste estudo foi caracterizar os diferentes estágios de maturação das células sanguíneas da serpente O. guibei, com base em estudos de microscopia, reações citoquímicas e aspectos ultraestruturais. Fragmentos de vértebras de serpentes recém-nascidas e adultas (n=11) foram coletados para obtenção da medula óssea que foi fixada em formol cálcio ou Bouin e processadas para histologia de rotina. Cortes histológicos, imprint de medula óssea e esfregaços sanguíneos foram corados com Rosenfeld, hematoxilina e eosina ou azul de metileno. As reações citoquímicas realizadas foram ácido periódico de Schiff (PAS), azul de toluidina (AT), Sudan Black B (SBB), benzidina peroxidase (PA) e fosfatase ácida (FA). Para a microscopia electrónica de transmissão (TEM), a medula óssea foi fixada em paraformaldeído a 4% + glutaraldeído 2%, em tampão Tyrode, pós fixados em tetróxido de ósmio a 1% e embebidos em resina Epon 812. A maior parte das células progenitoras de células sanguíneas foram identificadas em focos hematopoiéticos ativos na medula óssea de vértebras e costelas. As linhagens azurofílicas e linfoides foram morfologicamente similares aos de outros répteis. A linhagem granulocítica foi classificada como mieloblasto, promielócito, mielócito e granulócito maduro. Mielócitos podem ser diferenciados em basófilos com grânulos grandes, redondos e eletrondensidade homogênia ou heterófilos, com grânulos de tamanhos e formas variadas na análise MET. TB e PAS foram positivos nos grânulos imaturos e maduros basófilos. Por outro lado, heterófilos e azurófilos mostraram reação fortemente positiva para lípidos de SBB e BP. FA foi encontrado nos azurófilos em várias fases de maturação. As diferentes fases de eritrócitos foram classificadas como: proeritroblasto, eritroblasto basófilo, eritroblasto policromático, proeritrócitos e eritrócitos maduros. Os trombócitos apresentaram positivadade para PAS. As características dos trombócitos maduros e imaturos foram definidas através da TEM apresentando corpos densos, grânulos alfa, microtúbulos e sistema canalicular aberto. Concluindo, a medula óssea das costelas e vértebras é um importante foco hematopoético nas serpentes O. guibei recém-nascidas e adultas. Os aspectos morfológicos, citoquímicos e ultraestruturais são úteis para identificar e caracterizar os diferentes estágios de maturação das células sanguíneas / Hematopoiesis in snakes begins during embryogenesis and the process changes through fetal life. The first erytropoietic activity is extraembryonic from mesoderm cells of the yolk sac and during the embryonic development it becomes intraembryonic. In newborn and adult snakes, the main site of hematopoiesis occurs in the bone marrow. The aim of this study was to characterize different stages of blood cells maturation of O. guibei snakes, based on microscopic studies including cytochemical stains and ultrastructural features. Fragments of vertebrae of newborn and adult snakes (n= 11) were collected to obtain bone marrow that was fixed in Bouin or formol calcium and processed routinely for histology. Tissue sections, imprint of bone marrow and blood smears were stained with Rosenfeld, hematoxylin and eosin or methylene blue. The cytochemical reactions performed were periodic acid-Schiff (PAS), toluidine blue (AT), sudan black B (SBB), benzidine peroxidase (BP) and acid phosphatase (FA). For transmission electron microscopy (MET), bone marrow was fixed in paraformaldehyde 4% + glutaraldehyde 2% in Tyrode buffer, postfixed in 1% osmium tetroxide and embedded in Epon 812 resin. Most of progenitors of blood cells were identified in the active hematopoietic focus in bone marrow of vertebrae and ribs. The azurophilic and lymphocytic series were morphologically similar to those of other reptiles. Granulocytic lineage was classified as myeloblast, promyelocyte, myelocyte and mature granulocytes. Myelocyte can be differentiated into basophils, with large, round and electrondensity homogeneous granules or heterophils, with varied size and shapes granules in the TEM analysis. AT and PAS were positive in the immature and mature basophils granules. On the other hand, heterophils and azurophils showed strong positive reaction for lipids staining of SBB and BP. FA was found on azurophils in various stages of maturation. The different stages of erythrocytes were classified as: proerythroblast, basophilic erythroblast, polychromatic erythroblast, proerythrocyte and mature erythrocytes. Thrombocytics cells showed PAS positive. The characteristics of mature and immature thrombocytes were defined using TEM identifying the dense bodies, alpha granules, microtubules and open canalicular system. Concluding, the rib or vertebral bone marrow is an important hematopoietic site in the newborn and adult O. guibei snakes. The morphologic, cytochemical and ultrastructural characteristics are useful to identify and characterize different stages of maturation of blood cells
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Hematopoese em serpentes Oxyrhopus guibei (Hoge & Romano, 1978) (Ophidia: Dipsadidae): caracterização morfológica, citoquímica e ultraestrutural / Hematopoiesis in Oxyrhopus guibei (Hoge & Romano, 1978) (Ophidia: Dipsadidae) snakes: morphological, cytochemical and ultrastructural characterizationPriscila Aparecida Ozzetti 28 May 2013 (has links)
A hematopoese nas serpentes inicia-se durante a embriogênese e através dos processos de alterações da vida fetal. A primeira atividade eritropoética é extraembrionária, a partir de células mesodérmicas do saco vitelínico e durante o desenvolvimento embrionário torna-se intraembrionário. Em serpentes recém-nascidas e adultas, o principal foco hematopoético ocorre na medula óssea. O objetivo deste estudo foi caracterizar os diferentes estágios de maturação das células sanguíneas da serpente O. guibei, com base em estudos de microscopia, reações citoquímicas e aspectos ultraestruturais. Fragmentos de vértebras de serpentes recém-nascidas e adultas (n=11) foram coletados para obtenção da medula óssea que foi fixada em formol cálcio ou Bouin e processadas para histologia de rotina. Cortes histológicos, imprint de medula óssea e esfregaços sanguíneos foram corados com Rosenfeld, hematoxilina e eosina ou azul de metileno. As reações citoquímicas realizadas foram ácido periódico de Schiff (PAS), azul de toluidina (AT), Sudan Black B (SBB), benzidina peroxidase (PA) e fosfatase ácida (FA). Para a microscopia electrónica de transmissão (TEM), a medula óssea foi fixada em paraformaldeído a 4% + glutaraldeído 2%, em tampão Tyrode, pós fixados em tetróxido de ósmio a 1% e embebidos em resina Epon 812. A maior parte das células progenitoras de células sanguíneas foram identificadas em focos hematopoiéticos ativos na medula óssea de vértebras e costelas. As linhagens azurofílicas e linfoides foram morfologicamente similares aos de outros répteis. A linhagem granulocítica foi classificada como mieloblasto, promielócito, mielócito e granulócito maduro. Mielócitos podem ser diferenciados em basófilos com grânulos grandes, redondos e eletrondensidade homogênia ou heterófilos, com grânulos de tamanhos e formas variadas na análise MET. TB e PAS foram positivos nos grânulos imaturos e maduros basófilos. Por outro lado, heterófilos e azurófilos mostraram reação fortemente positiva para lípidos de SBB e BP. FA foi encontrado nos azurófilos em várias fases de maturação. As diferentes fases de eritrócitos foram classificadas como: proeritroblasto, eritroblasto basófilo, eritroblasto policromático, proeritrócitos e eritrócitos maduros. Os trombócitos apresentaram positivadade para PAS. As características dos trombócitos maduros e imaturos foram definidas através da TEM apresentando corpos densos, grânulos alfa, microtúbulos e sistema canalicular aberto. Concluindo, a medula óssea das costelas e vértebras é um importante foco hematopoético nas serpentes O. guibei recém-nascidas e adultas. Os aspectos morfológicos, citoquímicos e ultraestruturais são úteis para identificar e caracterizar os diferentes estágios de maturação das células sanguíneas / Hematopoiesis in snakes begins during embryogenesis and the process changes through fetal life. The first erytropoietic activity is extraembryonic from mesoderm cells of the yolk sac and during the embryonic development it becomes intraembryonic. In newborn and adult snakes, the main site of hematopoiesis occurs in the bone marrow. The aim of this study was to characterize different stages of blood cells maturation of O. guibei snakes, based on microscopic studies including cytochemical stains and ultrastructural features. Fragments of vertebrae of newborn and adult snakes (n= 11) were collected to obtain bone marrow that was fixed in Bouin or formol calcium and processed routinely for histology. Tissue sections, imprint of bone marrow and blood smears were stained with Rosenfeld, hematoxylin and eosin or methylene blue. The cytochemical reactions performed were periodic acid-Schiff (PAS), toluidine blue (AT), sudan black B (SBB), benzidine peroxidase (BP) and acid phosphatase (FA). For transmission electron microscopy (MET), bone marrow was fixed in paraformaldehyde 4% + glutaraldehyde 2% in Tyrode buffer, postfixed in 1% osmium tetroxide and embedded in Epon 812 resin. Most of progenitors of blood cells were identified in the active hematopoietic focus in bone marrow of vertebrae and ribs. The azurophilic and lymphocytic series were morphologically similar to those of other reptiles. Granulocytic lineage was classified as myeloblast, promyelocyte, myelocyte and mature granulocytes. Myelocyte can be differentiated into basophils, with large, round and electrondensity homogeneous granules or heterophils, with varied size and shapes granules in the TEM analysis. AT and PAS were positive in the immature and mature basophils granules. On the other hand, heterophils and azurophils showed strong positive reaction for lipids staining of SBB and BP. FA was found on azurophils in various stages of maturation. The different stages of erythrocytes were classified as: proerythroblast, basophilic erythroblast, polychromatic erythroblast, proerythrocyte and mature erythrocytes. Thrombocytics cells showed PAS positive. The characteristics of mature and immature thrombocytes were defined using TEM identifying the dense bodies, alpha granules, microtubules and open canalicular system. Concluding, the rib or vertebral bone marrow is an important hematopoietic site in the newborn and adult O. guibei snakes. The morphologic, cytochemical and ultrastructural characteristics are useful to identify and characterize different stages of maturation of blood cells
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Engineered human pluripotent stem cell lines for following differentiation into pancreatic islets and addressing their maturationZanfrini, Elisa 17 January 2024 (has links)
No description available.
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Extrathymic T cell receptor gene rearrangement in human alimentary tractBas, Anna January 2003 (has links)
<p>T lymphocytes regulate the initiation, duration, and magnitude of adaptive immune responses and function as effector cells in cell mediated immunity. To become immunologically competent they must generate functional antigen receptors. This process takes place in the thymus and requires somatic recombination of T cell receptor (TCR) genes. It is mediated by the endonucleases recombination activating gene-1 (RAG1) and RAG2. Although the thymus regresses at puberty, T cells are present throughout life implying that other tissues must provide the proper milieu for T cell development. This thesis describes extrathymic T cell maturation in man. RAG1, RAG2, and the preTα-chain (pTα), which is exclusively utilized in developing T cells, were used as markers for TCR gene rearrangement. Two new exons (1A and 1B) encoding sequences in the 5’ untranslated region (5’UTR) of mRNA were discovered in the human RAG1 gene. The previously described 5’UTR exon (renamed 1C) was located between the new exons and exon 2, the latter containing the entire coding sequence. We found that small intestinal lymphocytes of the T cell lineage expressed the new exons in three different splice forms. RAG1 mRNA containing the 1C exon was not expressed in small intestinal lymphocytes. In contrast, splice forms containing the 1A exon were not expressed in thymocytes. RAG1 and pTα mRNA expressing lymphocytes were seen both within the epithelium and in lamina propria. Thymocyte-like CD2<sup>+</sup>CD7<sup>+</sup>CD3<sup>-</sup>, CD4<sup>+</sup>CD8<sup>+</sup>, CD1a<sup>+</sup>, and IL7-R+ lymphocytes were identified in the small intestinal mucosa. CD2<sup>+</sup>CD7<sup>+</sup>CD3<sup>-</sup> cells had the highest expression levels of mRNA for RAG1 and pTα, suggesting that the small intestinal mucosa is indeed a site for T cell maturation. Small intestinal T lymphocytes were also shown to kill via the Fas/FasL pathway in a TCR/CD3 independent manner and via the perforin/granzyme pathway in a TCR/CD3 dependent manner. The Fas/FasL-mediated cytotoxicity may reflect an ongoing selection process of extrathymically maturated T cells. </p><p>The nasopharyngeal tonsil is the major inductive site for immune reactions against inhaled antigens. Previous demonstration of RAG1 expression in tonsillar B cells was interpreted as antigen driven receptor revision. The present study confirms the expression of RAG1 in B cells. We also found that RAG1, RAG2, and pTa mRNAs were expressed in lymphocytes of the T cell lineage. A small population of cells with the immature phenotype CD2+CD7+CD3- was demonstrated. This population had the highest expression levels of mRNA for RAG1, RAG2, pTα and terminal deoxynucleotidyl transferase. All four splice-forms of RAG1 mRNA were expressed. RAG1 and pTα mRNA expressing cells were mainly located in the proximity of the surface epithelium and in the outer rim of the follicles. These results suggest that the nasopharyngeal tonsil is a site where extrathymic T cell development and antigen driven TCR revision are occurring in parallel. </p><p>Celiac disease (CD) is a small intestinal enteropathy characterized by permanent intolerance to gluten. Gluten reactive intestinal T cells are central in the pathogenesis and CD can be regarded as a failure to maintain tolerance to this food antigen. Expression of the RAG1 1A/2 splice form was significantly decreased in small intestinal T cell subsets of CD patients suggesting that impaired TCR gene rearrangement could contribute to failure of maintain tolerance in CD. </p><p>Together, these findings show that both small intestinal and nasopharyngeal tonsillar lymphocytes of T cell lineage have the molecular machinery for antigen receptor rearrangement and that thymocyte-like lymphocytes are present in both tissues. Thus these organs are likely sites of T lymphocyte ontogeny as well as for secondary T cell receptor rearrangement in man. </p>
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Extrathymic T cell receptor gene rearrangement in human alimentary tractBas, Anna January 2003 (has links)
T lymphocytes regulate the initiation, duration, and magnitude of adaptive immune responses and function as effector cells in cell mediated immunity. To become immunologically competent they must generate functional antigen receptors. This process takes place in the thymus and requires somatic recombination of T cell receptor (TCR) genes. It is mediated by the endonucleases recombination activating gene-1 (RAG1) and RAG2. Although the thymus regresses at puberty, T cells are present throughout life implying that other tissues must provide the proper milieu for T cell development. This thesis describes extrathymic T cell maturation in man. RAG1, RAG2, and the preTα-chain (pTα), which is exclusively utilized in developing T cells, were used as markers for TCR gene rearrangement. Two new exons (1A and 1B) encoding sequences in the 5’ untranslated region (5’UTR) of mRNA were discovered in the human RAG1 gene. The previously described 5’UTR exon (renamed 1C) was located between the new exons and exon 2, the latter containing the entire coding sequence. We found that small intestinal lymphocytes of the T cell lineage expressed the new exons in three different splice forms. RAG1 mRNA containing the 1C exon was not expressed in small intestinal lymphocytes. In contrast, splice forms containing the 1A exon were not expressed in thymocytes. RAG1 and pTα mRNA expressing lymphocytes were seen both within the epithelium and in lamina propria. Thymocyte-like CD2+CD7+CD3-, CD4+CD8+, CD1a+, and IL7-R+ lymphocytes were identified in the small intestinal mucosa. CD2+CD7+CD3- cells had the highest expression levels of mRNA for RAG1 and pTα, suggesting that the small intestinal mucosa is indeed a site for T cell maturation. Small intestinal T lymphocytes were also shown to kill via the Fas/FasL pathway in a TCR/CD3 independent manner and via the perforin/granzyme pathway in a TCR/CD3 dependent manner. The Fas/FasL-mediated cytotoxicity may reflect an ongoing selection process of extrathymically maturated T cells. The nasopharyngeal tonsil is the major inductive site for immune reactions against inhaled antigens. Previous demonstration of RAG1 expression in tonsillar B cells was interpreted as antigen driven receptor revision. The present study confirms the expression of RAG1 in B cells. We also found that RAG1, RAG2, and pTa mRNAs were expressed in lymphocytes of the T cell lineage. A small population of cells with the immature phenotype CD2+CD7+CD3- was demonstrated. This population had the highest expression levels of mRNA for RAG1, RAG2, pTα and terminal deoxynucleotidyl transferase. All four splice-forms of RAG1 mRNA were expressed. RAG1 and pTα mRNA expressing cells were mainly located in the proximity of the surface epithelium and in the outer rim of the follicles. These results suggest that the nasopharyngeal tonsil is a site where extrathymic T cell development and antigen driven TCR revision are occurring in parallel. Celiac disease (CD) is a small intestinal enteropathy characterized by permanent intolerance to gluten. Gluten reactive intestinal T cells are central in the pathogenesis and CD can be regarded as a failure to maintain tolerance to this food antigen. Expression of the RAG1 1A/2 splice form was significantly decreased in small intestinal T cell subsets of CD patients suggesting that impaired TCR gene rearrangement could contribute to failure of maintain tolerance in CD. Together, these findings show that both small intestinal and nasopharyngeal tonsillar lymphocytes of T cell lineage have the molecular machinery for antigen receptor rearrangement and that thymocyte-like lymphocytes are present in both tissues. Thus these organs are likely sites of T lymphocyte ontogeny as well as for secondary T cell receptor rearrangement in man.
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Effet de Streptococcus Suis sur la capacité de présentation antigénique de cellules dendritiquesLetendre, 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.
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