Dissertationen zum Thema „Antigens, CD44 B-Lymphocytes Lymphocyte Activation“

Thesis (Ph.D. in Immunology) -- University of Colorado, 2006.
Typescript. Includes bibliographical references (leaves 277-285). Free to UCDHSC affiliates. Online version available via ProQuest Digital Dissertations;

CD4 T cells and B cells are cells associated with the adaptive immune system. The adaptive immune system is designed to mount a rapid antigen-specific response to pathogens by way of clonal expansions of T and B cells bearing discrete antigen-specific receptors. During viral infection, interactions between CD4 T cells and B cells occur in a dynamic process, where B cells that bind to the virus internalize and degrade virus particles. The B cells then present viral antigens to virus-specific CD4 T cells that activate the B cells and cause them to proliferate and differentiate into virus-specific antibody-secreting cells. Yet, non-specific hypergammaglobulinemia and the production of self-reactive antibodies occur during many viral infections, and studies have suggested that viral antigen-presenting B cells may become polyclonally activated by CD4 T cells in vivo in the absence of viral engagement of the B cell receptor. This presumed polyclonal B cell activation associated with virus infection is of great medical interest because it may be involved in the initiation of autoimmunity or contribute to the long-term maintenance of B cell memory. In order to directly examine the interactions that occur between T cells and B cells, I asked what would happen to a polyclonal population of B cells that are presenting viral antigens, if they were transferred into virus-infected hosts. I performed these studies in mice using the well-characterized lymphocytic choriomeningitis virus (LCMV) model of infection. I found that the transferred population of antigen-presenting B cells had two fates. Some antigen-expressing B cells were killed in vivo by CD4 T cells in the first day after transfer into LCMV-infected hosts. However, B cells that survived the cytotoxicity underwent a dynamic polyclonal activation manifested by proliferation, changes in phenotype, and antibody production. The specific elimination of antigen-presenting B cells following adoptive transfer into LCMV-infected hosts is the first evidence that MHC class II-restricted killing can occur in vivo during viral infection. This killing was specific, because only cells expressing specific viral peptides were eliminated, and they were only eliminated in LCMV-infected mice. In addition to peptide specificity, killing was restricted to MHC class II high cells that expressed the B cell markers B220 and CD19. Mice depleted of CD4 T cells prior to adoptive transfer did not eliminate virus-specific targets, suggesting that CD4 T cells are required for this killing. I found that CD4 T cell-dependent cytotoxicity cannot be solely explained by one mechanism, but Fas-FasL interactions and perforin are mechanisms used to induce lysis. Polyclonal B cell activation, hypothesized to be the cause of virus-induced hypergammaglobulinemia, has never been formally described in vivo. Based on previous studies of virus-induced hypergammaglobulinemia, which showed that CD4 T cells were required and that hypergammaglobulinemia was more likely to occur when virus grows to high titer in vivo, it was proposed that the B cells responsible for hypergammaglobulinemia may be expressing viral antigens to virus-specific CD4 T cells in vivo. CD4 T cells would then activate the B cells. However, because the antibodies produced during hypergammaglobulinemia are predominantly not virus-specific, nonvirus-specific B cells must be presenting viral antigens in vivo. In my studies, the adoptively transferred B cells that survived the MHC class II-restricted cytotoxicity became polyclonally activated in LCMV-infected mice. Most of the surviving naïve B cells presenting class II MHC peptides underwent an extensive differentiation process involving both proliferation and secretion of antibodies. Both events required CD4 cells and CD40/CD40L interactions to occur but B cell division did not require MyD88-dependent signaling, type I interferon signaling, or interferon γ signaling within B cells. No division or activation of B cells was detected at all in virus-infected hosts in the absence of cognate CD4 T cells and class II antigen. B cells taken from immunologically tolerant donor LCMV carrier mice with high LCMV antigen load became activated following adoptive transfer into LCMV-infected hosts, suggesting that B cells can present sufficient antigen for this process during a viral infection. A transgenic population of B cells presenting viral antigens was also stimulated to undergo polyclonal activation in LCMV-infected mice. Due to the high proportion of B cells stimulated by virus infection and the fact that transgenic B cells can be activated in this manner, I conclude that virus-induced polyclonal B cell activation is independent of B cell receptor specificity. This approach, therefore, formally demonstrates and quantifies a virus-induced polyclonal proliferation and differentiation of B cells which can occur in a B cell receptor-independent manner. By examining the fate of antigen-presenting B cells following adoptive transfer into LCMV-infected mice, I have been able to observe dynamic interactions between virus-specific CD4 T cells and B cells during viral infection. Adoptive transfer of antigen-presenting B cells results in CD4 T cell-mediated killing and polyclonal activation of B cells during LCMV infection. Studies showing requirements for CD4 T cells or MHC class II to control viral infections must now take MHC class II-restricted cytotoxicity into account. Polyclonal B cell activation after viral infection has the potential to enhance the maintenance of B cell memory or lead to the onset of autoimmune disease.

T and B-lymphocytes play an important role in an adaptive immune response. Communication between these two cells may result in either a humoral immune response or tolerance. Communication between T and B-lymphocytes involves a number of inducible cell surface molecules on both T and B-lymphocytes. It was the aim of this project to gain a greater understanding of the role of CD40 in the dynamic communication that occurs between naïve T-lymphocytes and resting B-lymphocytes during cognate communication. Because in vivo antigen specific T-lymphocytes are at low frequency, it is difficult to examine antigen-specific naïve T-lymphocytes. Thus, an in vitro system employing naïve antigen-specific T cell receptor (TCR) transgenic T cells and small resting B-lymphocytes that did not express CD40 was devised to examine the role of CD40 in cognate communication between naïve T-lymphocytes and resting B-lymphocytes. Upon recognition of antigen on resting B-lymphocytes that expressed CD40, T-lymphocytes proliferated, expressed the activation antigens CD69 and CD25, and remained responsive to subsequent antigen challenge. In the absence of CD40, resting B-lymphocytes did not induce sustained proliferation or sustained expression of the activation markers CD69 and CD25 on naïve T-lymphocytes, and their recovery was decreased compared to naïve T-lymphocytes that recognized antigen on resting B-lymphocytes that expressed CD40. Naïve T-lymphocytes, however, remained responsive to subsequent antigen challenge after recognition of antigen on resting CD40-/- B-lymphocytes. Recognition of antigen on resting CD40-/- B-lymphocytes also resulted in increased recovery and antigen responsiveness of T-lymphocytes when compared to controls without antigen, The role of CD40 in sustaining activation of naïve T-lymphocytes may be unique to resting B-lymphocytes, since proliferation of naïve T-lymphocytes in response to dendritic cells that did not express CD40 was similar to proliferation of naïve T-lymphocytes in response to dendritic cells that expressed CD40. The mechanism by which CD40 sustained activation of naïve T-lymphocytes was investigated by examining the induction of various costimulatory molecules on resting CD40+/- and CD40-/- B-lymphocytes during cognate interaction with naive T-lymphocytes. Induction of B7-1, upregulation of CD44 and ICAM-1, and sustained but not initial induction of B7-2 required that CD40 be expressed on resting B-lymphocytes. Expression of B7-1 and CD44H was not required for proliferation of naïve T-lymphocytes in response to antigen presented on resting B-lymphocytes. However, sustained expression of B7-2 was crucial for proliferation of naïve T-lymphocytes in response to antigen presented on resting B-lymphocytes.

La rencontre entre un lymphocyte T et une cellule présentatrice d'antigène (CPA) est un évènement central dans l'initiation et le développement de la réponse immunitaire adaptative. L'interaction entre ces deux cellules entraîne de nombreuses réorganisations moléculaires au niveau de l'aire de contact intercellulaire conduisant à la formation d'une structure dynamique et spécialisée remplissant diverses fonctions biologiques : la Synapse Immunologique (SI). Cette interaction permet à un lymphocyte T CD4+ helper (TH) de s'activer et de mettre en place une signalisation intracellulaire nécessaire à la production de cytokines. Le second aspect crucial de cette interaction consiste en la polarisation de la machinerie sécrétoire du lymphocyte TH vers la CPA permettant ainsi une activation sélective de la CPA présentant l'antigène spécifique et donc une amplification sélective de la réponse immunitaire. Les lymphocytes T CD4+ CD25+ régulateurs naturels (Treg) jouent un rôle capital dans le maintien de la tolérance périphérique au soi, leur absence conduisant au développement de syndromes lymphoprolifératifs auto-immuns. Les Treg sont également impliqués dans le contrôle des réponses immunitaires anti-infectieuses et ont un rôle délétère lors des réponses immunitaires anti-tumorales. Différents mécanismes de régulation impliquant le contact cellulaire ou bien la sécrétion de molécules effectrices solubles ont à ce jour été décrits. Mon travail de thèse a été de déterminer si les Treg humains pourraient inhiber les réponses immunitaires en altérant la polarisation des lymphocytes TH vers les CPA. Afin de répondre à cette question, nous avons utilisé des approches de microscopie confocale afin de visualiser un Treg et un lymphocyte TH interagissant simultanément avec une même CPA. Nous avons pu observer que les Treg inhibent la polarisation de la machinerie sécrétoire des lymphocytes TH (appareil de Golgi et cytosquelette de tubuline) vers la CPA via la production locale de TGF-bêta. L'obtention de ces résultats nous a permis d'identifier un nouveau mécanisme de suppression, qui pourrait permettre de mieux appréhender l'incroyable potentiel des Treg à réguler finement les réponses immunitaires
The encounter between a T lymphocyte and an antigen presenting cell (APC) is a central event in the initiation and development of adaptative immune responses. Interaction between these two cells leads to multiple molecular reorganizations of the intercellular contact site leading to the formation of a dynamical and specialized structure filling diverse biological functions: the Immunological Synapse (IS). This interaction enables a CD4+ T helper lymphocyte (TH) to activate and to put into place an intracellular sustained signaling necessary for cytokine production. The second key feature of this interaction consists in TH lymphocyte secretory machinery polarization towards APC thereby allowing a selective activation of the APC presenting the specific antigen and thus a selective amplification of the immune response. CD4+ CD25+ natural regulatory T lymphocytes (Treg) play a pivotal role in the maintenance of peripheral self tolerance, their absence leading to the development of autoimmune lymphoproliferative disorders. Treg are also involved in controlling anti-infectious immune responses and have a deleterious role during anti-tumoral immune responses. To date, different regulation mechanisms involving cellular contact or the secretion of soluble effector molecules have been described. My thesis work was to determine if human Treg could inhibit immune responses by altering polarization of TH lymphocytes towards APC. In order to answer this question we used confocal microscopy approaches so as to visualize a Treg and a TH lymphocyte simultaneously interacting with a same APC. We were able to observe that Treg inhibit secretory machinery polarization of TH lymphocytes (Golgi apparatus and tubulin cytoskeleton) towards APC via local TGF- production. These results enabled us to identify a novel suppression mechanism that could allow to better apprehend the incredible potential of Treg to finely regulate immune responses

Stimulation of CD40 on APCs through CD40L expressed on helper CD4+ T cells activates and “licenses” the APCs to prime CD8+ T cell responses. While other stimuli, such as TLR agonists, can also activate APCs, it is unclear to what extent they can replace the signals provided by CD40-CD40L interactions. In this study, we used an adoptive transfer system to re-examine the role of CD40 in the priming of naïve CD8+ T cells. We find an approximately 50% reduction in expansion and cytokine production of TCR-transgenic T cells in the absence of CD40 on all APCs, and on dendritic cells in particular. Moreover, CD40-deficient and CD40L-deficient mice fail to develop endogenous CTL responses after immunization and are not protected from a tumor challenge. Surprisingly, the role for CD40 and CD40L are observed even in the absence of CD4+ T cells; in this situation, the CD8+T cell itself provides CD40L. Furthermore, we show that although TLR stimulation improves T cell responses, it cannot fully substitute for CD40. We also investigated whether CD40-CD40L interactions are involved in the generation, maintenance, and function of memory CD8+ T cells. Using a virus infection system as well as a dendritic cell immunization system, we show that the presence of CD40 on DCs and other host APCs influences the survival of activated effector cells and directly affects the number of memory CD8+ T cells that are formed. In addition, memory CD8+ T cell persistence is slightly impaired in the absence of CD40. However, CD40 is not required for reactivation of memory CD8+ T cells. It seems that CD40 signals during priming also contribute to memory CD8+ T cell programming but this function can be independent of CD4+T cells, similar to what we showed for primary responses. Altogether, these results reveal a direct and unique role for CD40L on CD8+ T cells interacting with CD40 on APCs that affects the magnitude and quality of primary as well as memory CD8+ T cell responses.

Das Knochenmark (BM) beherbergt wesentliche Komponenten des adaptiven Immunsystems, die einen langfristigen Schutz gegen wiederkehrende Pathogene vermitteln können, sodass es sich als Reservoir für ein immunologisches Gedächtnis qualifiziert. Neben langlebiger Antikörper-produzierender Plasmazellen bleiben auch Antigen (Ag)-spezifische CD8+ und CD4+ T-Gedächtniszellen dauerhaft im Knochenmark erhalten, auch wenn sie in den sekundären lymphoiden Organen (SLOs) und im Blut abwesend sind. Es wird angenommen, dass diese T-Gedächtniszellen bei erneutem Kontakt mit den gleichen systemischen Pathogenen schnell reagieren können. Allerdings sind die biologischen Mechanismen für ihre langfristige Aufrechterhaltung immer noch umstritten und demnach ungeklärt. Unklar ist auch, wie die T-Gedächtniszellen des Knochenmarks bei erneuter Konfrontation mit demselben Antigen reagieren. Hier wird dieser Frage begegnet, indem durch klassiche Immunisierung mit definieren Antigenen eine stabile Population Ag-spezifischer CD8+ und CD4+ T-Gedächtniszellen im Knochenmark erzeugt wird.
The bone marrow (BM) harbors critical components of the adaptive immune system being able to provide long-lasting protection against previously encountered pathogens, thus qualifying as a reservoir of immunological memory. In addition to long-lived antibody producing plasma cells, antigen (Ag)-specific CD8+ and CD4+ memory T lymphocytes are maintained long-term in the BM even when they are absent from secondary lymphoid organs (SLOs) and blood. Those memory T cells are thought to respond fast upon re-encounter of systemic pathogens. However, the biological mechanisms behind their long-term maintenance in the BM are still a matter of debate and thus remain unclear. Similarly, it is also unclear how the memory T cells of the BM react to antigenic re-challenge. Here we address these issues by generating a stable pool of Ag-specific CD8+ and CD4+ memory T lymphocytes in the BM by classical immunizations with defined antigens.

Professional antigen presenting cells (APCs) represent an important link between the innate and adaptive immune system. Macrophages (MΦs) and dendritic cells (DCs) serve as sentinels in the periphery collecting samples from their environment and processing this information. These cells then present antigenic fragments to T cells in the context of self-MHC molecules. Although a clear role for both of these APCs in the stimulation of already activated or memory T cells has been established, the ability of MΦs to activate naive T cells is still unknown. In this thesis the ability of bone marrow-derived MΦs and DCs to prime naive CD8+ and CD4+ T cells was investigated. Using adoptively transferred transgenic CFSE-Iabeled P-14 T cells, specific for gp33 from lymphocytic choriomeningitis virus in the context of Db, we were able to demonstrate the ability of both MΦs and DCs to induce naive CD8+ T cells proliferation. Once primed by MΦs these T cells gained effector function as shown by interferon- γ (IFN-γ) production and in vivo cytolysis. In addition, immunization of wild type animals with gp33-pulsed MΦs, as well as DCs, led to greater than a 95% reduction in lymphocytic choriomeningitis virus titers. To rule out the role of cross-presentation in the observed priming, two models were used. In the first model, lethally irradiated F1 bxs chimeras reconstituted with either H-2s or H-2b bone marrow were used as host for the adoptive transfer experiments. Since the gp33 peptide binds to Db, the H-2s reconstituted animals should be unable to cross-present the peptide to the P-14 T cells. Using this model, we were able to clearly demonstrate the ability of MΦs to activate naive P-14 T cells to undergo division. Additional experiments, demonstrated that these MΦ primed T cells went on to develop into effector cells. Finally, the ability of the MΦ primed T cells to develop into functional memory cells was demonstrated. To confirm the chimera results, these experiments were repeated using β2 microglobulin deficient animals (whose cells don't express MHC I) as host in adoptive experiments. MΦs were able to stimulate the naive P-14 T cells to divide and gain effector function as demonstrated by the ability to produce IFN-γ. In contrast to the CD8 system, MΦ were poor stimulators of D011.10 CD4+ T cell proliferation. Additionally, D011.10 T cells stimulated by DCs were able to produce interleukin-2 (IL-2), IL-4, tumor necrosis factor and granulocyte-macrophage colony stimulating factor where as MΦ stimulated D011.10 T cells were only able to produce IL-2. In conclusion this body of work clearly demonstrates the in vivo ability of MΦ to stimulate CD8+ T cell proliferation, effector function, as well as the formation of functional CD8+ T cell memory. Whether or not the nature of the memory pools stimulated by the two APCs is exactly the same is still unknown and needs further investigation. The ability of APCs other than DCs to stimulate functional protective memory needs to be considered in the quest to design vaccines that offer broad-spectrum protection.

The Tec family tyrosine kinases Itk, Tec and Rlk are expressed in T cells. Previous studies have established that these kinases are critical for TCR signaling, leading to the activation of PLCγ1. To further understand the functions of Tec kinases in T cell activation, we took three different approaches. First, we performed a thorough analysis of CD28-mediated signaling events and functional responses with purified naïve T cells from Itk-/- mice and a highly controlled stimulation system. Data from this set of studies definitively demonstrate that CD28 costimulation functions efficiently in naïve CD4+ T cells in the absence of Itk. Second, in order to further study the functions of Tec kinases in vivo, we generated transgenic mouse lines expressing a kinase-dead (KD) mutant of Tec on the Itk-/-Rlk-/- background, hoping to study mice that are functionally deficient for all three Tec kinases. The results hint the importance of the Tec kinases in T cell development and/or survival. Finally, in order to identify potential transcriptional targets of Itk, we used microarray technology to compare global gene expression profiles of naïve and stimulated Itk-/- versus Itk+/- CD4+ T cells. This analysis provided a short list of differentially expressed genes in Itk-/- versus Itk+/- CD4 T cells, providing a starting point for further studies of Itk in T cell activation. Collectively, these studies clarified the role of Itk in CD28 signaling, revealed some unexpected aspects of Tec family kinases in T cells, and indicated potential targets of Itk-dependent signaling pathways in T cells.

Immunologic self-tolerance is maintained by both central and peripheral mechanisms. Furthermore, regulation of mature lymphocyte responses is governed by inhibitory as well as stimulatory signals. TCR recognition of cognate peptide bound to MHC molecules provides the initial stimulus leading to T lymphocyte activation and determines the antigen specificity of any subsequent response. However, lymphocytes must discriminate between foreign and self antigens presented by self-MHC molecules to maintain self tolerance and avoid pathological autoimmunity. Consequently, TCR ligation alone is reported to result in abortive activation, T cell anergy, apoptosis, and tolerance. Under normal physiological conditions, costimulatory signals modify lymphocyte responsiveness to TCR ligation to prevent autoimmunity while enabling robust responses to foreign antigen. Members of the CD28/B7 superfamily provide the critical secondary signals essential for normal immune cell function. CD28 is an essential positive costimulatory molecule with critical functions in thymic development, lineage commitment, and regulation of peripheral lymphocyte responses to antigenic stimuli. CD28 ligation by APC-expressed B7 molecules alters proximal signaling events subsequent to MHC/TCR interactions, and initiates unique signaling pathways that alter mRNA stability and gene transcription. Furthermore, CD28 signaling is required for regulatory T cell development and function. Thus, CD28 has a central role in both potentiating lymphocyte activation mediated by TCR engagement and regulating peripheral tolerance. In contrast, Ctla-4 mediates an inhibitory signal upon binding B7 molecules on an antigen-presenting cell. Its importance in governing lymphocyte responses is manifested in the fatal lymphoproliferative disorder seen in Ctla-4-/- mice. The lymphocyte proliferation is polyclonal, antigen and CD28 dependent, and arises from defects in peripheral CD4+T cell regulation. The high percentage of peripheral T lymphocytes expressing activation markers is accompanied by lymphocyte infiltration into numerous non-lymphoid tissues and results in death by 3-4 weeks. While still controversial, Ctla-4 signaling has been reported to be essential for induction of peripheral T lymphocyte tolerance in vivo and in some model systems is proposed to regulate both T lymphocyte anergy induction and the immune suppressive effects of some regulatory T cells in the prevention of autoimmunity. Signaling pathways activated by TCR ligation and CD28 costimulation have been extensively characterized. In contrast, the mechanisms mediating Ctla-4 maintenance of tolerance remain largely unknown. Ctla-4 gene expression is tightly controlled during T cell development and activation, and its intracellular localization and expression on the cell surface is regulated by numerous pathways and intermediates. While a tailless Ctla-4 mutant is capable of inhibiting T cell activation, recent studies have shown that a ligand independent form of Ctla-4 is also capable of providing an inhibitory signal to T lymphocytes. In conjunction with the strictly controlled expression kinetics and the perfect amino acid homology between the intracellular domains of mouse and human Ctla-4, this data suggests that Ctla-4 may participate in the modulation or initiation of intracellular signaling pathways. Positive and negative costimulatory receptors on the T cell modify lymphocyte responses by altering both quantitative and qualitative aspects of the lymphocyte response including threshold of activation, cytokine secretion, and memory responses. Positive costimulation augments T cell responses, in part, by downregulating the expression of genes that actively maintain the quiescent phenotype. This study was initiated to determine the role of Ctla-4 ligation in modifying the global gene expression profile of stimulated T cells and to determine if the Ctla-4 mediated maintenance of T cell tolerance was achieved, in part, by altering the transcription of quiescence genes necessary for the prevention of T cell activation subsequent to TCR and CD28 stimulation. Previous studies investigating the influence of Ctla-4 ligation on transcriptional profiles of activated lymphocytes detected only quantitative alterations in the transcriptional regulation initiated by CD28 signaling. In contrast, our data suggests that quantitative effects of Ctla-4 ligation that differentially influence pathways acting downstream of stimulatory receptors results in a stable and qualitatively unique phenotype detectable at the level of the transcriptome. Thus, the cumulative effect of Ctla-4 signaling is unique and not constrained to reversing alterations in expression initiated by CD28. In addition, Ctla-4 ligation can be shown to influence T lymphocyte responsiveness and the resulting global expression profile within 4 hours after stimulation and prior to detectable Ctla-4 surface expression. In a subpopulation of T cells, TCR stimulation activates pathways that result in commitment to activation with 2-6 hours. In contrast, CD28 signaling must be maintained for 12-16 hours to ensure maximal responses at the population level. The period of sensitivity to Ctla-4 inhibition of activation is more constrained and does not extend beyond 12 hours. Together, these data support a potential role for Ctla-4 in modification of the early transcriptional response and may explain various alterations in phenotype resulting from Ctla-4 ligation that have been reported in secondary responses. Identification of genes involved in lymphocyte activation, maintenance of selftolerance, and attenuation of immune responses opens the door to therapeutic manipulation of the pathways implicated. CD28 costimulation results in general amplification of TCR-initiated transcriptional responses, and specifically alters the expression profile of a subset of genes. In contrast, Ctla-4 ligation directly and specifically alters the expression of a select group of genes when ligated, and results in minimal suppression of the global CD28-mediated costimulatory transcriptional response. Ctla-4 regulated genes comprise a heterogeneous family, but include known quiescence factors, transcriptional regulators, and various determinants of cell cycle progression and senescence. The role of Ctla-4 in maintaining self-tolerance indicates that targeted manipulation of these gene products presents a novel therapeutic opportunity, and suggests that the mechanisms involved in Ctla-4-mediated maintenance of peripheral T cell tolerance and regulation of immune responsiveness is more nuanced than previously thought. In addition, this study provides the most comprehensive description of global gene expression during primary lymphocyte activation yet available. The integration of statistical and bioinfomatics analyses with large scale data mining tools identifies genes not previously characterized in lymphocytes and can direct future work by predicting potentially interacting gene products and pathways.

L'activation des lymphocytes T est un événement fondamental de la réponse immunitaire adaptative. Elle est déclenchée par la transduction du signal médiée par le complexe TCR/CD3.Le mécanisme de déclenchement du signal via le TCR reste, mal compris. Mon projet de thèse vise à examiner la contribution des PI(4,5)P2 dans le mécanisme du déclenchement du signal TCR. L'expression ectopique d'une phosphatase spécifique de PIP2 a permis de réduire de 50% les PI(4,5)P2 membranaires. L'analyse du profil de phosphorylations spécifiques des tyrosines montre que l'expression ectopique de cette 5-phosphatase augmente les événements de phosphorylation à l'état basal comparés à des conditions analogues pour des cellules contrôles. En revanche, alors que suite à l'engagement du TCR par le complexe MHC-peptide indépendamment du co-récepteur CD4 nous observons une augmentation des phosphorylations, l'activation par le complexe MHC-peptide CD4 dépendant semble affectée. Nous avons analysé la contribution des PI(4,5)P2 dans la dynamique membranaire du TCR grâce à la technique svFCS. PIP2 peuvent jouer un rôle essentiel dans la régulation de la dynamique latérale du TCR à la membrane plasmique. Enfin, nous avons observé que l'inhibition par la néomycine (aminoglycoside qui en tant que polycation peut se lier et neutraliser le groupement anionique de PI(4,5)P2), aboutit à des changements similaires dans la dynamique membranaire du TCR et la régulation proximale dans des cellules T primaires murines CD4+. Ensemble, nos données révèlent le rôle régulateur fondamental de PI(4,5)P2 dans la dynamique membranaire du TCR et de CD4, pour le contrôle de l'initiation des voies de signalisation du TCR
PI(4,5)P2 plays important roles in a large spectrum of membrane-based cellular activities . It is therefore surprising that it is currently not known if PI(4,5)P2 is also involved in the T cell receptor (TCR) signal transduction mechanism. We investigate here the role of PI(4,5)P2 in the regulation of the TCR membrane dynamics and signaling initiation using a combination of biophysical, biochemistry and cell biology approaches. Ectopic expression of the Inp54p, a 5-phophatase that hydrolyzes PI(4,5)P2 into PI(4)P, with a membrane targeting signal specifically decreased by 50% of the PI(4,5)P2 in a CD4+ T cell hybridoma. Interestingly, we observed that this decrease caused modified TCR (and CD4 co-receptor) dynamics in the plasma membrane. The lateral diffusion switched from a regime dominated by dynamic partitioning in the cholesterol- and sphingolipid-dependent nanodomains into one dominated by dynamic partitioning in the actin cytoskeleton-assisted nanodomains. This switch was associated with a change in activation of the TCR and proximal signaling pathways both at the basal level and upon stimulation. Upon pMHC engagement, the CD4-independent activation of the TCR signaling pathways was found significantly augmented while that of CD4-dependent was affected. We further provided evidence for the involvement of PI(4,5)P2 in the Finally, we found that inhibition of interactions between PI(4,5)P2 and endogenous proteins with neomycin resulted in the modified TCR membrane dynamics and proximal signaling in primary murine CD4+ T cells. Altogether, our data reveal that PI(4,5)P2 is crucially involved in the control of the activation of TCR early signaling pathways

Une réplication résiduelle et une évolution génétique du HIV-1 semblent pouvoir persister chez les sujets recevant un traitement antirétroviral. Notre étude du tropisme viral dans les réservoirs cellulaires a mis en évidence une sélection progressive de virus utilisant le corécepteur d'entrée CXCR4, ainsi qu'une compartimentalisation cellulaire des quasi-espèces virales sous traitement antirétroviral. L'infection par des virus X4 est associée à un défaut de reconstitution du taux de lymphocytes T CD4 sous traitement antirétroviral. La production thymique et l'export d'émigrants thymiques récents dans le compartiment T CD4 naïf périphérique semblent conservés chez les sujets ayant un défaut de reconstitution immunitaire. La persistance de taux élevés d'activation et d'apoptose lymphocytaire T pourrait être responsable d'une destruction périphérique accrue des T CD4.

La mémoire immunologique est le mécanisme biologique fondamental à la base du développement de la vaccination. La compréhension de ce mécanisme ainsi que de ses interactions avec les différents acteurs du système immunitaire a permis l’élaboration de vaccins qui sont aujourd’hui les garants d’une protection accrue face à l’émergence de maladies infectieuses potentiellement mortelles. La voie d’injection et le mode de transfert de ces vaccins sont des paramètres majeurs à prendre en considération car ils définissent une modulation des réponses immunitaires et de leurs spécificités d’action. De nos jours, seule la voie intramusculaire demeure la voie majoritaire d’administration de vaccins lors de la prophylaxie primaire en santé humaine. Au cours de notre étude, nous nous sommes intéressés à comparer l’injection d’un antigène (l’ovalbumine) selon deux voies d’administration : la voie intramusculaire et la voie intradermique. Nous nous sommes également appuyés sur une technologie du laboratoire qui consiste à transférer des gènes par des vecteurs AAV2/1 recombinants. Nous disposions de deux constructions de ces vecteurs ayant une spécificité pour cibler les cellules musculaires et permettant l’apport d’un effet auxiliaire par les lymphocytes T CD4+ lors d’injections dans des souris femelles. De plus, une de ces constructions nous permettait d’éviter la voie de présentation directe de l’antigène par les cellules dendritiques (DCs) aux lymphocytes T CD8+. Les capacités modulatrices de ces vecteurs nous permirent de montrer pour la première fois que le vecteur AAV2/1 recombinant était capable de faire exprimer un transgène au sein de la peau et d’y générer une réponse cellulaire forte. Nous avons également montré qu’il existait une synergie d’action entre l’effet auxiliaire et la voie intradermique qui améliorait considérablement les réponses cellulaires issues de la présentation croisée d’antigène. Enfin, nous avons pu démontrer que les lymphocytes T CD8+ générés suite à cette synergie d’action présentaient un profil phénotypique de cellules mémoires polyfonctionnelles et capables de protéger l’hôte face à un challenge pathogénique
Immunological memory is the fundamental biological mechanism at the beginning of the development of vaccination. Understanding this mechanism and its interactions with the various players of the immune system has allowed the development of vaccines that are today the most effective barrier against the emergence of life-threatening infectious diseases. Route of injection and the nature of carriers of these vaccines are key parameters to be taken into consideration because they define a modulation of immune responses and their specific features. Nowadays, only the intramuscular injection route remains the major route of vaccines injection in the context of primary prophylaxis in human health. During our study, we were interested in comparing the injection of antigen (ovalbumin) following two routes of administration: intramuscular and intradermal routes. We also relied on a technology in the laboratory that involves the transfer of genes by rAAV2/1 vectors. We had two constructs of these vectors having specificity to target skeletal muscle cells and allowing us to provide a helper effect from CD4+ T cells during injections into female mice recipients. Moreover, one of these constructs enabled us to avoid the direct presentation of antigens by dendritic cells (DCs) to CD8+ T cells. The capacity of modulation of these vectors allowed us to show for the first time that the rAAV2/1 vector was able to trigger the expression of a transgene in the skin, and there to generate a strong cellular response. We have also shown that CD4+ T cell help and the intradermal route of immunization synergize to improve greatly cellular responses from the cross-presentation of antigens. Finally, we have demonstrated that CD8+ T cells generated following this synergism exhibited a phenotypic profile of polyfunctional memory cells and able to protect the host against a pathogenic challenge

Les lymphocytes B jouent un rôle central dans l’immunité humorale par leur capacité à présenter des antigènes aux lymphocytes T, à sécréter des cytokines et à se différencier en plasmocytes produisant des anticorps. Ces fonctions peuvent être induites par leur stimulation in vitro. Par leur aptitude à présenter des antigènes indépendamment de la spécificité du récepteur des lymphocytes B (BCR), les lymphocytes B peuvent être utilisés comme cellules présentatrices d’antigènes (antigen-presenting cells, APC) afin d’induire la réponse cellulaire des lymphocytes T CD8+ cytotoxiques spécifiques. L’immunité cellulaire est cruciale pour prévenir les infections contre certains virus et en immunothérapie du cancer. L’objectif général de ces travaux est d’étudier la biologie des lymphocytes B. Plus particulièrement, nous souhaitons comprendre et améliorer leur fonction de présentation d’antigène afin d’utiliser les lymphocytes B comme source alternative d’APC. Dans la première partie de ces travaux, notre attention s’est portée sur la compréhension du mécanisme de présentation croisée par le complexe majeur d’histocompatibilité de classe I (CMH-I) par lequel un épitope de la protéine gp100 du mélanome, inséré dans une nanoparticule pseudo-virale (VLP) composée de la protéine de surface du virus de la mosaïque de la papaye (PapMV), est présenté par les lymphocytes B. Cette VLP est une plateforme vaccinale capable de stimuler le système immunitaire sans l’aide d’adjuvant et facilite la présentation croisée de l’épitope inséré, de façon indépendante de l’activité du protéasome. Les résultats obtenus démontrent que l’apprêtement de l’épitope inséré dans la nanoparticule s’effectue selon une voie de présentation croisée vacuolaire qui dépend de l’activité de la cathepsine S, de l’acidification des lysosomes et requiert l’induction de l’autophagie. Ainsi, nous avons défini plus précisément le mécanisme de présentation croisée par lequel les lymphocytes B apprêtent et présentent un épitope inséré dans la VLP de PapMV. Par la suite, nous avons cherché à améliorer le protocole d’activation in vitro permettant d’amplifier et d’induire les fonctions de présentation d’antigènes des lymphocytes B, dans le but d’utiliser ces cellules pour activer les réponses cellulaires des lymphocytes T CD8+ cytotoxiques. Les stimulations in vitro des lymphocytes B par le CD40 ligand (CD40L) et l’interleukine (IL)-21 ou la combinaison de l’IL-4 et l’IL-21 au lieu de l’activation standard avec le CD40L et l’IL-4 ont été évaluées. Nos résultats ont approfondi nos connaissances de la biologie des lymphocytes B. Nous avons démontré que la stimulation des lymphocytes B avec le CD40L et l’IL-21 augmente leur prolifération, mais mène à leur différenciation en plasmocytes sécrétant des anticorps. Au contraire, la stimulation avec le CD40L et l’IL-4 induit efficacement leur fonction de présentation d’antigènes. La stimulation des lymphocytes B avec le CD40L et la combinaison de l’IL-4 et de l’IL-21 augmente leur prolifération, mène seulement faiblement à leur différenciation en cellules sécrétrices d’anticorps, mais induit efficacement leur fonction de présentation d’antigènes. Nous avons démontré pour la première fois que cette méthode permet de générer des APC puissantes capables d’induire la réponse des lymphocytes T CD8+ cytotoxiques in vitro. Nos résultats nous permettent de postuler que ces cellules pourraient être capables de mener à une réponse cellulaire in vivo. En tant qu’APC efficaces, les lymphocytes B pourraient être utilisés dans une stratégie vaccinale ou être employés comme APC afin d’améliorer les traitements d’immunothérapie du cancer par transfert adoptif de lymphocytes T. Ainsi, les travaux présentés dans cette thèse ont porté tant sur la compréhension des mécanismes de présentation croisée d’un épitope inséré dans la VLP de PapMV par les lymphocytes B, que sur l’amélioration de la méthode permettant d’induire leur fonction de présentation d’antigènes pour activer les lymphocytes T CD8+ cytotoxiques. Ces travaux de recherche fondamentale ont permis de contribuer à des avancées sur les connaissances de la biologie des lymphocytes B. Ils offrent de nouvelles pistes de réflexion quant aux utilisations biotechnologiques des lymphocytes B comme source alternative d’APC pour des applications de recherche fondamentale et clinique telles que la vaccination et les traitements d’immunothérapie du cancer.
B lymphocytes are central to humoral immunity due to their ability to present antigens to T cells, secrete cytokines and to differentiate into antibody-producing plasma cells. These functions can be induced by their in vitro stimulation. Being able to present antigens independently of the specificity of their B cell receptor (BCR), B cells can be used as antigen-presenting cells (APC) to induce specific cytotoxic CD8+ T cell cellular responses. Cellular immunity is crucial to prevent infections against viruses and in cancer immunotherapy. The main aim of this thesis is to study B cell biology. Specifically, we aim to deepen our understanding of their antigen presentation function and improve this function to use B cells as an alternative source of APC. First, we focused on deciphering the class I major histocompatibility complex (MHC-I) cross-presentation mechanism by which an epitope from gp100 melanoma protein, inserted in a virus-like particle (VLP) made of the coat protein of the papaya mosaic virus (PapMV), is presented by B cells. This VLP is a vaccine platform able to stimulate the immune system with no adjuvant and mediate a proteasome independent cross-presentation of the inserted epitope. Our results show that the inserted epitope is processed through a vacuolar pathway dependent on cathepsin S activity, lysosome acidification and requires the induction of autophagy. Thus, we provide a more detailed characterization of the mechanism used by B cells to process and cross-present an epitope inserted in PapMV VLP. Secondly, we aimed to improve the in vitro activation protocol used to expand B cells and induce their antigen presentation functions to use these cells to trigger cytotoxic CD8+ T cell cellular responses. We evaluated the in vitro stimulation of B cells with CD40 ligand (CD40L) and interleukin (IL)-21 or the combination of IL-4 and IL-21 instead of the standard activation method based on CD40L and IL-4. Our results deepen our knowledge of B cell biology. We showed that stimulating B cells with CD40L and IL-21 increases their proliferation but leads to their differentiation in antibody-producing plasma cells. In comparison, the stimulation with CD40L and IL-4 efficiently induces their antigen presentation function. The stimulation of B lymphocytes with CD40L and the combination of IL-4 and IL-21 increases their proliferation, weakly leads to their differentiation in antibody-secreting cells but is very efficient in inducing their antigen presentation function. We show for the first time that this method can generate potent APC able to induce cytotoxic CD8+ T cell responses in vitro. Our results allow us to hypothesize that these cells could be capable of triggering cellular immunity in vivo. As efficient APC, B cells could be used in a vaccination strategy or be employed as APC to improve cancer immunotherapy treatments such as adoptive cell transfer of T lymphocytes. Thus, the work presented in this thesis provides a deeper understanding of the antigen cross-presentation pathway by which B cells process and present an epitope inserted in PapMV VLP. It also reports an improved method to induce antigen presentation function of B cells to stimulate cytotoxic CD8+ T cells. This research work constitutes a leap forward in fundamental B cell research by increasing our knowledge of B cell biology. It also brings new opportunities regarding biotechnological uses of B cells as an alternative source of APC for fundamental and clinical applications such as vaccination and cancer immunotherapy treatments.