Global ETD Search

1	The role of Fyn and B-cell expressed ADAM10 in early B cell development, germinal center formation and terminal B cell differentiation Chaimowitz, Natalia 01 January 2012 (has links) In these studies we sought to determine the role of Fyn kinase and ADAM10 in B cell biology. A disintegrin and metalloproteinase 10 (ADAM10) is a zinc dependent proteinase related to matrix metalloproteinases. ADAM10 has emerged as a key regulator of cellular processes by cleaving and shedding extracellular domains of multiple transmembrane receptors and ligands. In particular, ADAM10 has been identified as a key regulator of lymphocyte development. Here we report that ADAM10 is dispensable for early B cell development within the bone marrow. However, deletion of ADAM10 from all peripheral B cells or in post-switch cells leads to severe impairments in humoral responses. When ADAM10 was deleted from all peripheral B cells a decrease in antigen specific IgG production was seen both with respect to serum levels and IgG ASCs, indicating that plasma cell (PC) differentiation is influenced. Cells producing high affinity antigen specific antibodies were particularly affected, consistent with defects in germinal center (GC) reactions. Moreover, changes in lymphoid architecture were also observed. Consistent with these findings, follicular dendritic cell (FDC)-reticula was undetectable following immunization. On the other hand, when ADAM10 was deleted in post-switch B cells, GC formation and lymphoid architecture were not impaired. Despite normal architecture, however, antibody production was still affected, likely due to abnormal gene expression in ADAM10-deficient PCs. Consistent with this hypothesis, PCs isolated from ADAM10Δ/ΔIgG1-cre+/- showed decreased expression of genes that facilitate plasma cell differentiation and function and increased expression of Bcl6, an inhibitor of PC differentiation. Fyn kinase is a member of the Src protein tyrosine kinase. Fyn is widely expressed in many cell types, including lymphocytes. Fyn has been shown to interact with both the B cell and T cell receptor (BCR and TCR, respectively). While Fyn-deletion did not impair the development of immature T cells and B cells, TCR signaling was altered in mature T cells. Our results demonstrate that Fyn-KO mice have significantly low basal levels of IgG1 and IgG2a. Additionally, these mice displayed delayed kinetics in the production of NP-specific IgG1 and IgG2b, and significantly low NP-specific IgG2a after a T-dependent immunization protocol. Defects in antibody production correlated with significantly reduced numbers of GC B cells, TFH cells and splenic PCs. Moreover, Fyn-KO B cells showed decreased production antibody following in vitro activation. Our results thus demonstrate that Fyn-mediated signaling and B cell ADAM10 expression are necessary for optimal humoral responses. B cells Germinal Centers Humoral Responses Immunology Medicine and Health Sciences
2	Kinetics and phenotype of the draining lymph node and pulmonary B cell response to an influenza A virus-like particle vaccine Goldman, Lea Nichole 01 May 2013 (has links) Influenza A virus (IAV) infection is a serious respiratory disease associated with significant morbidity and mortality worldwide. Annual vaccination is the most effective way to prevent infection and its potentially severe complications; however, the vaccines currently offered have several drawbacks that limit its availability and protective efficacy. Influenza virus-like particles (VLPs), which lack viral genetic material and are non-infectious, represent a promising vaccine candidate. Previous reports have shown VLPs are more immunogenic than subunit or recombinant proteins, and confer protection upon lethal challenge. A critical component of this protection is mediated by influenza HA-specific neutralizing Abs produced by memory B cells and plasma cells, the cellular products of the germinal center (GC) reaction. While preliminary studies have examined the humoral immune response to VLP vaccination, the current study is the first to characterize the GC response in secondary and tertiary lymphoid tissues. Mice were vaccinated with influenza VLPs using three immunization routes: subcutaneous (s.c.), intramuscular (i.m.), and intranasal (i.n.) and the GC response was assessed over time. Robust GC reactions were induced in the dLNs regardless of vaccination route, though the largest response was generated with VLPs s.c. The pattern of isotype expression was remarkably similar between routes, with IgM+ and IgG2+ B cells representing the majority of the GC B cell population. Mucosal immune responses in the upper (nasal) and lower (lung) airway were measured in mice vaccinated i.n. Marked GC reactions were induced in the nasal-associated lymphoid tissue (NALT), while the pulmonary response was relatively modest and short-lived compared to infection with IAV. Within the GC B cell population, IgM+ and IgG2+ B cells made up the majority, similar to the dLN response. Importantly, the pattern of isotype expression induced by VLPs mimicked the response induced by natural IAV infection, and suggests that VLPs contain the necessary innate immune agonists to induce a TH1 biased response. B cells Germinal Centers iBALT Influenza vaccine VLPs Pathology
3	Formation of germinal centres in the rat Vonderheide, Robert H. January 1988 (has links) No description available. 611
4	Celluar and molecular aspects of the germinal center reaction Dahlenborg, Katarina. January 1998 (has links) Thesis (doctoral)--Lund University, 1998. / Added t.p. with thesis statement inserted. Includes bibliographical references.
5	Caractérisation des mécanismes cellulaires, génétiques et épigénétiques de la différenciation terminale des lymphocytes B chez l’homme / Characterization of the cellular, genetic and epigenetic mechanisms of human terminal B cell differentiation Hussein, Mourad 13 December 2013 (has links) Ces dernières années ont été marquées par une progression importante dans la connaissance de la physiologie des cellules B in vivo et de leur différenciation en plasmocytes, grâce aux modèles murins et à l'imagerie intravitale. La transposition à l'Homme des connaissances acquises chez la souris soulève cependant des difficultés, telles que le manque d'outils pour visualiser les évènements qui se déroulent dans les organes lymphoïdes humains. Dans l'optique d'apporter une réponse à cette problématique, nous avons développé au sein du laboratoire un modèle in vitro en deux étapes, permettant la différenciation des lymphocytes B naïfs humains en plasmocytes. Ce modèle est particulièrement adapté pour étudier l'induction, au cours de la différenciation terminale B, des voies de signalisation, des facteurs de transcription et des grands processus cellulaires tels que la prolifération ou la mort programmée. A l'aide de ce modèle, nous avons mené deux études relatives à la différenciation B dans le centre germinatif: (i) La caractérisation sur le plan phénotypique et fonctionnel des populations cellulaires générées in vitro. Par une approche transcriptomique, nous avons comparé le profil d'expression et identifié les gènes et fonctions biologiques spécifiques à chacune de ces populations différenciées. Nous nous sommes concentrés sur l'étude de l'expression et de l'activité de l'enzyme AID, notamment au travers de la mesure des fréquences des hypermutations somatiques à chaque stade de la différenciation. (ii) L'étude des mécanismes cellulaires (cycle cellulaire, apoptose), génétiques et épigénétiques menant à la transition des cellules du centre germinatif vers le stade de plasmablastes. Cette étude a permis de caractériser au plus près une population cellulaire fondatrice à l'origine des cellules différenciées. En outre, nous avons mis en évidence l'importance de la méthylation de l'ADN, en particulier la 5-hydroxyméthylation, dans le contrôle de la différenciation terminale B. / Within the past few years there has been a significant increase in the knowledge of B cell physiology in vivo and their differentiation into plasma cells through the implementation of murine models and intravital imaging. However, the transposition of this knowledge from mouse to man raises difficulties such as the lack of tools available to visualize the ongoing events in human lymphoid organs. In order to overcome this issue, we have developed in our laboratory, a two-step in vitro model allowing naive B cell differentiation into plasma cells. This model is particularly suitable for studying the induction of signaling pathways, transcription factors and major cellular processes such as proliferation or programmed cell death. Using this model, we conducted two studies on B cell differentiation in the germinal center: (i) phenotypic and functional characterization of cell populations generated in vitro. This study involved a transcriptomic approach which identified and compared the expression profile of specific genes and their biological functions within each of these differentiated populations. Specifically, we focused on the expression and activity of the AID enzyme through the measurement of somatic hypermutation frequency at each stage of differentiation. (ii) The study of cellular (cell cycle, apoptosis), genetic and epigenetic mechanisms leading to the transition of the germinal center B cells into plasmablasts. This study allowed us to characterize a founder cell population of the in vitro generated plasmablasts. In addition, we have highlighted the importance of DNA methylation, in particular 5- hydroxymethylation in controlling terminal B cell differentiation. Immunologie Différenciation Centre germinatif Lymphocyte B Plasmablastes Méthylation Aicda Immunology B cells Differentiation Germinal centers Methylation
6	Peripheral Germinal Centers Regulate Virus-Specific B Cell Accumulation in the CNS Atkinson, Jeffrey Ross 01 May 2018 (has links) No description available. Neurosciences Immunology Biomedical Research germinal centers B cells APRIL coronavirus memory B cells antibody-secreting cells CNS viral infection virus-specific B cells
7	Caractérisation de la réponse adaptative humorale contre le streptocoque du groupe B Gaudreau, Annie 07 1900 (has links) Le streptocoque du groupe B (GBS) est un agent causant des septicémies et des méningites chez les nouveaux nés et chez les adultes. Une réaction sérologique dirigée contre la capsule polysaccharidique (CPS) permet de différencier les 10 sérotypes de GBS, dont le sérotype III qui est le plus fréquemment isolé en cas de méningite. Actuellement l’efficacité de l’unique traitement disponible, l’antibioprophylaxie intrapartum, est controversée. Dans l’optique d’élargir les options de prévention, cette étude vise à mieux comprendre les interactions entre GBS III et le développement de la réponse adaptative, sujet qui est peu documenté. Cette étude a évalué, par cytométrie en flux (FACS), les sous-populations des lymphocytes B (LB) spléniques impliquées suite à l’infection systémique de GBS III dans un modèle in vivo. De plus, la réponse humorale contre GBS III et contre la CPS III purifiée ainsi que la formation des centres germinatifs (GCs) spléniques dans un contexte de multiples infections par GBS ont été évalués. Les résultats suggèrent que la première infection stimule la production d’anticorps contre GBS III mais peu contre sa CPS. De plus, GBS III activerait la différenciation des LB et induirait la formation des GCs liée au déclenchement d’une réponse mémoire permettant un meilleur contrôle lors des infections subséquentes. Malgré sa faible immunogénicité, la CPS ne semblerait pas interférer avec le développement de l’immunité adaptative humorale contre la bactérie. La production d’anticorps contre GBS III qui implique la commutation de classe serait principalement produite contre des épitopes différents de ceux composant la CPS III. / Group B Streptococcus (GBS) is an agent of septicemia and meningitis in newborns but also in adults. A serological reaction directed against the polysaccharide capsule (CPS) allows to differentiate 10 GBS serotypes, including serotype III which is the most frequently isolated in cases of meningitis. Currently the effectiveness of the only available treatment, intrapartum antibiotic prophylaxis, is controversial. To improve prevention strategies, this study aims to better understand the interactions between GBS and the development of the adaptive response, a subject that is poorly documented. This study evaluated, by flow cytometry (FACS), the splenic subpopulations of B lymphocytes (LB) involved following systemic GBS infection in an in vivo model. This study also evaluated the serum anti-GBS antibody response and against its purified capsule as well as the formation of splenic germinal centers (GCs) in the context of multiple GBS infections. Results suggest that the first infection stimulates the production of antibodies against GBS III but little against its capsule. Furthermore, results suggest that GBS activates B cell differentiation by inducing the production of GCs, which are linked to triggering a memory response allowing better control in subsequent infections. Despite its low immunogenicity, the CPS does not appear to interfere with the development of adaptive humoral immunity against the bacteria. Therefore, the production of antibodies against GBS III, involving class switching, would recognize different epitopes from those found on its capsule. Streptocoque du groupe B capsule polysaccharidique infections multiples réponse humorale lymphocytes B centres germinatifs commutation de classe modèle in vivo Group B Streptococcus capsular polysaccharide multiple infections humoral response germinal centers class switching in vivo
8	Regulation of the germinal center reaction by T helper cells and T regulatory cells Wu, Hao 11 April 2016 (has links) Indiana University-Purdue University Indianapolis (IUPUI) / Germinal Centers (GCs) are transient lymphoid structures that arise in lymphoid organs in response to T cell-dependent antigen. Within the GC, follicular T helper (TFH) cells promote GC B cell differentiation and in turn the proper antibody production to protect us from invading pathogens. We wished to study the regulation of this process by transcription factors STAT3 and Bcl6. STAT3 is important for both TFH cell differentiation and IL-4 production by Th2 cells. IL-4 is a major functional cytokine produced by TFH cells. To dissect the role of STAT3 in IL-4 production by TFH cells, we generated T cell-specific conditional STAT3 knockout mice (STAT3KO). Compared to WT mice, TFH cell differentiation in STAT3KO mice was partially impaired, both in spleen following sheep red blood cells (SRBC) immunization and in Peyer's patches (PPs). In STAT3KO mice, the numbers of splenic GC B cells were markedly decreased, whereas PP GC B cells developed at normal numbers and IgG1 class switching was greatly increased. Unexpectedly, we found that STAT3 intrinsically suppressed the expression of IL-4 and Bcl6 in TFH cells. Mechanistically, in vitro repression of IL-4 expression in CD4 T cells by Bcl6 required STAT3 function. Apart from TFH cells, the GC reaction is also controlled by regulatory follicular T helper (TFR) cells, a subset of Treg cells. To study the mechanism of how TFR cells regulate the GC reaction, we generated mice specifically lacking TFR cells by specifically deleting Bcl6 in Treg cells. Following immunization, these "Bcl6FC" mice developed normal TFH and GC B cell populations. However, Bcl6FC mice produced altered antigen-specific antibody responses, with reduced titers of IgG and increased IgA. Bcl6FC mice also developed IgG antibodies with significantly decreased avidity to antigen in an HIV-1 gp120 "prime-boost" vaccine model. Additionally, TFH cells from Bcl6FC mice produced higher levels of Interferon-γ, IL-10 and IL-21. Loss of TFR cells therefore leads to highly abnormal TFH and GC B cell responses. Overall, our studies have uncovered unexpected regulatory roles of STAT3 in TFH cell function as well as the novel regulatory roles of TFR cells on cytokine production by TFH cells and on antibody production. Antibody production Bcl6 Follicular T helper cell Germinal center Regulatory follicular T helper cell Stat3 Germinal centers Lymph nodes Lymphoid tissue Th2 cells Lymphocytes Cytokines Cell differentiation Immunoglobulins Pathogenic microorganisms Transcription factors
9	ROLE OF FDCs AND FDC ACTIVATION IN PROMOTING HUMORAL IMMUNITY INCLUDING RESPONSES TO T-DEPENDENT ANTIGENS IN THE ABSENCE OF T CELLS El, Sayed Rania 16 June 2009 (has links) Follicular dendritic cells (FDCs) reside in primary B-cell follicles and in the light zones of germinal centers (GCs) in secondary follicles, where their dendrites interdigitate forming extensive networks intimately interacting with B-cells. In GCs, FDCs can be found at the edges attached to the supporting reticular fibers. They trap and arrange immune complexes (ICs) in vivo and in vitro in a periodic manner with 200–500Å spacing and provide both antigen-specific and non-specific accessory signals to B-cells. FDCs exist in resting and activated states, with two characteristically different phenotypes. In their activated state, FDCs upregulate the expression of accessory molecules and cytokines important in the FDC-B cell interaction in GCs. We sought to determine the mechanisms influencing the transition of FDCs from a resting to an activated state in GCs and their impact on T-cell dependent (TD) and independent (TI)-GC reactions (GCRs). We found that IC-FDC interactions via FDC-FcgammaRIIB induce the upregulation of FDC-FcgammaRIIB, -ICAM-1, and -VCAM-1, at both the protein and mRNA levels. We also reported for the first time the expression of TLR-4 on FDCs. Moreover, engagement of FDC-TLR4 with LPS activated NF-kappaB, up-regulated expression of important FDC-accessory molecules, including FcgammaRIIB, ICAM-1, and VCAM-1, and enhanced FDC accessory activity in promoting recall IgG responses. Moreover, IC-activated FDCs produced IL-6 and FDC-IL-6 promoted GCRs, somatic hypermutation (SHM) and IgG production. Further, we reported that binding of FDCs to collagen coated surfaces induced restoration of their dendritic processes and networks in vitro. In addition, we designed an FDC-supported in vitro model capable of induction and assessment of primary human antibody responses to protein antigens characterized by class-switching and affinity maturation. Uniquely, we generated TI immune responses to TD protein Ags in the complete absence of T cell help in vivo and in vitro. In the presence of FDC-associated second signals such as BAFF and C4BP, FDC- FcgammaRIIB-periodically trapped-ICs induced the production of Ag-specific IgM, GC-development and plasmablast-differentiation in anti-Thy-1-pretreated nude mice. Purified murine and human B cells cultured in vitro with IC-bearing FDCs also showed the production of antigen–specific IgM within just 48 h. Follicular Dendritic Cells Humoral Immunity T-dependent Antigens Germinal Centers IL-6 FcgammaRIIB TLR-4 Immune Complexes Collagen type I IgG Somatic Hypermutation T-Independent In vitro Vaccine Assessment Primary Human Antibody Response Secondary Follicle Activation Accessory Activity Dendrites BAFF C4BP IgM Periodicity ICAM VCAM Medicine and Health Sciences
10	Elucidating the role of BCL6 in helper T cell activation, proliferation, and differentiation Hollister, Kristin N. January 2014 (has links) Indiana University-Purdue University Indianapolis (IUPUI) / The transcriptional repressor BCL6 has been shown to be essential for the differentiation of germinal center (GC) B cells and follicular T helper (TFH) cells. The interaction of TFH and GC B cells is necessary for the development of high affinity antibodies specific for an invading pathogen. Germline BCL6-deficient mouse models limit our ability to study BCL6 function in T cells due to the strong inflammatory responses seen in these mice. To overcome this, our lab has developed a new BCL6 conditional knockout (cKO) mouse using the cre/lox system, wherein the zinc finger region of the BCL6 gene is flanked by loxP sites. Mating to a CD4-Cre mouse allowed us to study the effects of BCL6 loss specifically in T cells, without the confounding effects seen in germline knockout models. Using this cKO model, we have reaffirmed the necessity of BCL6 for TFH differentiation, including its role in sustained CXCR5 surface expression, a signature marker for TFH cells. This model also allowed us to recognize the role of BCL6 in promoting the expression of PD-1, another key surface marker for TFH cells. Without BCL6, CD4+ T cells cannot express PD-1 at the high levels seen on TFH cells. Our discovery of DNMT3b as a target for BCL6 suggests BCL6-deficient T cells have increased DNA methyltransferase activity at the PD-1 promoter. This data establishes a novel pathway for explaining how BCL6, a transcriptional repressor, can activate genes. Experiments with the BCL6 cKO model have also established a role for BCL6 in naïve CD4+ T cell activation. Furthermore, we did not observe increased differentiation of other helper T cell subsets, in contrast to what has been reported elsewhere with germline BCL6-deficient models. Unexpectedly, we found decreased T helper type 2 (Th2) cells, whereas mouse models with a germline mutation of BCL6 have increased Th2 cells. These results indicate that BCL6 activity in non-T cells is critical for controlling T cell differentiation. Finally, using an HIV-1 gp120 immunization model, we have, for the first time, shown BCL6-dependent GCs to be limiting for antibody development and affinity maturation in a prime-boost vaccine scheme. T cells follicular T helper cells BCL6 germinal center HIV vaccine T cells -- Differentiation Cell transformation -- Regulation Repressors, Genetic -- Research HIV (Viruses) -- Vaccination AIDS vaccines -- Research Inflammation -- Immunological aspects B cells -- Research -- Analysis Germinal centers Immune system Autoimmune diseases Mice -- Diseases -- Molecular aspects Animal models in research

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