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Itpkb and Ins(1,3,4,5)P4 control proapoptotic Bim gene expression and survival in B cellsMarechal, Yoann 25 June 2008 (has links)
L’Ins(1,3,4,5)P4 produit par l’Ins(1,4,5)P3 3-kinase de type B (Itpkb) est nécessaire au développement des thymocytes et lymphocytes T murins. Trois hypothèses sont admises quant à la fonction physiologique et au mécanisme d’action de cet inositol phosphorylé : la première postule que l’Ins(1,3,4,5)P4 module la réponse calcique intracellulaire ; la seconde, que cet inositolphosphate est un intermédiaire métabolique dans la synthèse d’inositols plus hautement phosphorylés ; la dernière, que l’Ins(1,3,4,5)P4 module la localisation subcellulaire et la fonction de protéines capables de la reconnaître par des domaines spécifiques de liaison. Afin d’investiguer cette dernière hypothèse, nous avons analysé la physiologie des lymphocytes B invalidés pour Itpkb et avons généré et analysé des souris transgéniques d’addition pour Rasa3, récepteur potentiel à l’Ins(1,3,4,5)P4.
Les lymphocytes B déficients en Itpkb présentent un défaut de survie car ils ne peuvent activer correctement les protéines kinases Erk1/2 suite à la stimulation du BCR de surface. Cela conduit à la surexpression anormale de la protéine pro-apoptotique Bim. La diminution de l’expression de Bim est suffisante dans ce modèle pour restaurer une fonction normale des lymphocytes B. In vitro, Nous avons montré que l’Ins(1,3,4,5)P4 est nécessaire à la translocation de Rasa3, protéine favorisant l’inactivation de la voie de Ras, de la membrane vers le cytoplasme. L’étude de lymphocytes invalidés pour Itpkb dans un modèle de BCR transgénique semble montrer que des anomalies de réponse calcique ne participent pas au phénotype.
En conclusion, nos résultats indiquent qu’une des voies de signalisation préférentielle de l’Ins(1,3,4,5)P4 passe par la modulation de la localisation subcellulaire de protéines possédant un domaine d’affinité pour l’Ins(1,3,4,5)P4 telle que Rasa3.
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Regulation of lymphocyte development and function by TRAF2 and TRAF3Gardam, Sandra, Clinical School - St Vincent's Hospital, Faculty of Medicine, UNSW January 2008 (has links)
Tumour necrosis factor receptor (TNFR) family members are widely expressed in cells of the immune system and are essential for the development and function of many immune cell types. The TNFR associated factor (TRAF) family are signal adapter molecules that are recruited to various members of the TNFR family and are important for the transduction of signals downstream of these receptors. In these studies, gene targeting was used to create a mouse capable of undergoing conditional inactivation of the Traf3 gene. These mice were studied alongside previously generated mice that were similarly genetically modified with respect to the Traf2 gene. The mice produced lacked expression of either TRAF2 or TRAF3 in either B or T cells. In resting B cells TRAF2 and TRAF3 were shown to cooperate to negatively regulate the signalling of B cell activating factor of the TNF family (BAFF) and its receptor (BAFF-R), the TNF ligand and receptor pair that provide obligate survival signals to B cells. Thus, TRAF2- and TRAF3-deficient B cells displayed hyperactive NF-kB2 signalling, an increased ability to survive, and almost identical gene expression profiles, emphasizing the cooperative nature of their roles in resting B cells. Importantly, the survival of these B cells was completely independent of BAFF. In normal B cells, BAFF signalling was shown to lift the negative regulation of survival mediated by TRAF2 and TRAF3, by depleting TRAF3 from the cell. This process was shown to require TRAF2. T cells deficient in TRAF2 or TRAF3 also displayed hyperactivity of the NF-kB2 pathway, but they did not accumulate in vivo or show extended survival in vitro. Mice lacking TRAF2 or TRAF3 in their T cells did however display a decrease in the number of memory phenotype CD8+ T cells. These studies indicate that some of the roles of TRAF2 and TRAF3 are common between B and T cells. However, the consequences of loss of TRAF2 or TRAF3 in B and T cells differs considerably, presumably due to the differential TNFR expression and usage by each cell type.
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Regulation of lymphocyte development and function by TRAF2 and TRAF3Gardam, Sandra, Clinical School - St Vincent's Hospital, Faculty of Medicine, UNSW January 2008 (has links)
Tumour necrosis factor receptor (TNFR) family members are widely expressed in cells of the immune system and are essential for the development and function of many immune cell types. The TNFR associated factor (TRAF) family are signal adapter molecules that are recruited to various members of the TNFR family and are important for the transduction of signals downstream of these receptors. In these studies, gene targeting was used to create a mouse capable of undergoing conditional inactivation of the Traf3 gene. These mice were studied alongside previously generated mice that were similarly genetically modified with respect to the Traf2 gene. The mice produced lacked expression of either TRAF2 or TRAF3 in either B or T cells. In resting B cells TRAF2 and TRAF3 were shown to cooperate to negatively regulate the signalling of B cell activating factor of the TNF family (BAFF) and its receptor (BAFF-R), the TNF ligand and receptor pair that provide obligate survival signals to B cells. Thus, TRAF2- and TRAF3-deficient B cells displayed hyperactive NF-kB2 signalling, an increased ability to survive, and almost identical gene expression profiles, emphasizing the cooperative nature of their roles in resting B cells. Importantly, the survival of these B cells was completely independent of BAFF. In normal B cells, BAFF signalling was shown to lift the negative regulation of survival mediated by TRAF2 and TRAF3, by depleting TRAF3 from the cell. This process was shown to require TRAF2. T cells deficient in TRAF2 or TRAF3 also displayed hyperactivity of the NF-kB2 pathway, but they did not accumulate in vivo or show extended survival in vitro. Mice lacking TRAF2 or TRAF3 in their T cells did however display a decrease in the number of memory phenotype CD8+ T cells. These studies indicate that some of the roles of TRAF2 and TRAF3 are common between B and T cells. However, the consequences of loss of TRAF2 or TRAF3 in B and T cells differs considerably, presumably due to the differential TNFR expression and usage by each cell type.
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Contribution of Glucose Metabolism to the B Lymphocyte ResponsesDufort, Fay Josephine January 2012 (has links)
Thesis advisor: Thomas C. Chiles / B-lymphocytes respond to environmental cues for their survival, growth, and differentiation through receptor-mediated signaling pathways. Naïve Blymphocytes must acquire and metabolize external glucose in order to support the bioenergetics associated with maintaining cell volume, ion gradients, and basal macromolecular synthesis. The up-regulation of glycolytic enzyme expression and activity via engaged B-cell receptor mediated-events was glucose-dependent. This suggests an essential role for glucose energy metabolism in the promotion of B cell growth, survival, and proliferation in response to extracellular stimuli. In addition, the activity of ATP-citrate lyase (ACL) was determined to be crucial for ex vivo splenic B cell differentiation to antibody-producing cells wherein B cells undergo endomembrane synthesis and expansion. This investigation employed knockout murine models as well as chemical inhibitors to determine the signaling components and enzymes responsible for glucose utilization and incorporation into membrane lipids. These results point to a critical role for phosphatidylinositol 3- kinase (PI3K) in orchestrating cellular glucose energy metabolism and glucosedependent de novo lipogenesis for B lymphocyte responses. / Thesis (PhD) — Boston College, 2012. / Submitted to: Boston College. Graduate School of Arts and Sciences. / Discipline: Biology.
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An investigation into the biology and function of protein Icb-1Cheng, Daian January 2013 (has links)
In this thesis I describe an investigation into the function of the protein Icb-1, a homologue of Themis1 in B cells and monocytes. Themis1 is important for T cell positive and negative selections. Yet its function in T cell development is not clear. Although it shows characteristics of an adaptor protein and involvement in TCR-induced signalling, the exact signalling defects in Themis1-/- T cells remain obscure. Icb-1 is similar to Themis1 in sequence, function and binding partners. It has been studied in human tumour and macrophage cell lines, leading to limited conclusions. Its role in B cells has never been published. Given the link with Themis1, it is of great interest to investigate the function of Icb-1. My study has been focused on the comparison between Icb-1 knockout mice with wild-type controls. I characterised the B cell development in Icb-1-/- mice, either naturally born or produced as mixed adult bone marrow chimeras reconstituted from WT and Icb-1-/- donor cells. I examined the possible compensation and redundancy of Themis1 and Icb-1, by characterising Thems1/Icb-1 double knockout mice. The Ig-HEL mouse models were used to examine the change in B cell repertoire due to negative and positive selections. The mice were challenged with SRBCs or NP-CGG to examine the germinal centre response to foreign antigen when Icb-1 is absent. In vitro stimulation of B cells with soluble and membrane-bound antigens was used to investigate early B cell responses in detail and to give insights into the defects found in in vivo challenges. Finally, I examined the BCR-induced phosphorylation of key signalling molecules and Ca2+ flux in splenic B cells. The study revealed largely normal B cell development with subtle selection impairments, but a partially defected B cell immune response to antigens in Icb-1-/- mice. The marginal zone B cell population was enlarged in the absence of Icb-1, while the positive selection of B1 B cells induced by intracellular self-antigen was impaired. The deficient mice showed a reduction in germinal centre B cell generation. The defects are associated with impaired BCR-induced cell signalling to low abundance and/or low avidity antigens. In particular, Ca2+ flux and Erk1/2 phosphorylation were clearly reduced under certain conditions. The results shine a light on the function of protein Icb-1, and also improve our knowledge of Themis1 and the Themis family. They provide a new avenue of investigation into the regulation of BCR signalling, especially in Ca2+ flux induction and Erk1/2 activation. They also provide insight into how differential signalling is controlled within cells during activation and differentiation in response to antigens that vary in terms of affinity, avidity and frequency.
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Mechanisms of TLR signaling and cooperation in B lymphocytesBuchta, Claire Marie 01 May 2014 (has links)
B lymphocytes play important roles in antibody production, cytokine production, and antigen presentation to T cells. Ligation of Toll-like receptors (TLRs) on B cells stimulates cellular activation and B cell effector functions. Synergistic activation of other receptors such as CD40 or the B cell receptor (BCR) with TLR ligation further enhances B cell activation and effector functions. The tumor necrosis factor receptor associated factor (TRAF) family of proteins act as cytoplasmic signaling adaptor molecules and moderate downstream signaling from both the tumor necrosis factor receptor (TNFR) superfamily of proteins, including CD40, and the IL-1R/TLR superfamily of proteins.
To date, only TRAFs 3 and 6 have been shown to be involved in TLR signaling, with TRAF6 providing positive regulation and TRAF3 providing negative regulation of TLR signaling in B cells. Deficiency in another TRAF family member, TRAF5, has been implicated in the development of atherosclerosis, a disease developed in part due to TLR dysregulation. Here, we addressed the hypothesis that TRAF5 is a negative regulator of TLR signaling.
We found that TRAF5 negatively regulated TLR-mediated cytokine and antibody production in B lymphocytes. The enhanced cytokine production seen in TLR-stimulated TRAF5 KO B cells was not attributable to altered cellular survival or proliferation, but instead more cytokine was produced on a per-cell basis, likely due to enhanced MAPK pathways after TLR ligation. Additionally, TRAF5 deficiency did not dramatically affect cytokine production in TLR-stimulated bone marrow-derived macrophages or dendritic cells, suggesting that TRAF5 plays a greater role in TLR signaling in lymphoid versus myeloid cells. TRAF5 associated with the TLR signaling proteins MyD88 and TAB2, and negatively regulated the association of TAB2 with its binding partner TRAF6.
Furthermore, we manipulated B cell activation via ligation of various TLRs, CD40, and/or the BCR in order to activate the cells to effectively present antigen. Activated B cells pulsed with antigen served as an effective cellular vaccine and offered protection against both an infectious pathogen (Listeria monocytogenes) and a model of murine melanoma. We identified two candidate activation criteria for B cell vaccines (Bvacs): stimulation through the BCR and TLR7, and stimulation through CD40 and TLR4. Additionally, we found that high IL-6 production by the activated Bvac was essential for inducing optimal CD8+ T cell memory. These B cell activation protocols offer significant advantages over those currently being tested for clinical use. Understanding B cell activation through TLRs is a critical step in developing new therapies against cancer and infectious disease.
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A Study of TGF‐β Signaling in B Lymphocytes and GlioblastomaSchilling, Stephen January 2009 (has links)
<p>Transforming growth factor–β (TGF–β) signaling regulates a range of processes in a variety of cell types. Consequently, TGF–β plays a complex role in the progression of several types of cancers; it acts as a tumor suppressor in normal cells and early in tumor progression, yet it can promote tumor progression in later stages of cancer.</p><p>Among the cancers that TGF–β has been implicated in is glioblastoma multiforme (GBM), the most common primary brain neoplasm and one of the most lethal types of cancer. Because of its high mortality rate and the lack of effective treatments, discovering the molecular mechanisms that underlie GBM formation and growth is of great clinical interest. To this end, we investigated the function of a TGF–β target gene — the putative tumor suppressor N‐Myc downstream‐regulated gene 4 (NDRG4) — in GBM cell viability, proliferation and tumor formation. Contrary to the established roles of other NDRG family members, we found that NDRG4 expression is elevated in GBM and that NDRG4 is required for the survival of established GBM cell lines and primary GBM xenograft cells enriched for highly tumorigenic GBM cancer stem cells. Knockdown of NDRG4 expression results in G<sub>1</sub> cell cycle arrest followed by apoptosis that is associated with a decrease in the expression of XIAP and survivin. Finally, knockdown of NDRG4 expression in established GBM cell lines and GBM cancer stem cells results in decreased tumorigenicity following intracranial implantation of these cells into immunocompromised mice. Collectively, these data indicate that NDRG4 does not function as a tumor suppressor like other NDRG family members, but rather it is essential for GBM tumorigenicity and may represent a potential therapeutic target for this devastating disease.</p><p>In the second portion of this dissertation, we examine the TGF–β cytostatic signaling pathway in B lymphocytes. TGF–β–induced growth inhibition is the most extensively studied biological response to a TGF–β signal. Although in most cell types this response is mediated by Smad3– dependent regulation of c–Myc, p15<super>Ink4B</super>, and p21<super>Cip1</super> transcription, studies from Smad3 null mice suggest that TGF–β–induced growth inhibition in B lymphocytes occurs regardless of Smad3 status. We prove that this response does indeed occur independently of Smad3 in purified primary B lymphocytes and WEHI–231 cells. Consistent with this, p15<super>Ink4B</super> and p21<super>Cip1</super> are not noticeably induced by TGF–β in these cells, whereas Id3 and cyclin G2 are induced in a Smad3–independent manner. Finally, unlike the MAPK pathways we tested, the BMP–specific Smads 1 and 5 are activated in response to TGF–β in these cells, and this activation is dependent on ALK5 kinase activity. Collectively, these data indicate that TGF–β induces growth inhibition in B lymphocytes through a novel signaling pathway, and Smads 1 and 5 may help mediate this response.</p> / Dissertation
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Toll-like receptor modulation of disease relevant B cell responsesRieger, Aja. January 1900 (has links)
Thesis (M.Sc.). / Written for the Dept. of Microbiology and Immunology. Title from title page of PDF (viewed2009/07/02 ). Includes bibliographical references.
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Clonal Studies of Human B CellsSu, Kuei-Ying January 2015 (has links)
<p>B lymphocytes are multifunctional and play important roles in both innate and adaptive immunity. The diverse roles of B cells can be attributed to the various and distinct types of B cells as determined by their origin, developmental stage, antigen specificity, and function.</p><p>Evidence suggests that human innate-like B cells (i.e., marginal zone and/or B1-like B cells) develop during fetal life. However, the characteristics of human fetal B-lineage cells are less understood. Recent studies of fetal and human umbilical cord B cells indicated that CD27, a well-established marker of human memory B cells, may also be expressed on human B1-like B cells. Indeed, CD27+ B cells are present in patients with hyper-IgM 1 (HIGM1) syndrome who are unable to generate GCs or memory B cells. In order to define the origin of naïve CD27+IgD+ human B cells, I studied B-cell development in both fetal and adult tissues.</p><p>In human fetal liver, most CD19+ cells co-express CD10, a marker of human developing B cells. Some CD19+CD10+ B cells express CD27, and these fetal CD27+ cells are present in the pro-B, pre-B, and immature/transitional B-cell compartments. Lower frequencies of phenotypically identical cells are also identified in adult bone marrow. CD27+ pro-B, pre-B, and immature/transitional B cells express recombination activating gene-1, terminal deoxynucleotidyl transferase, and Vpre-B mRNA comparable to their CD27− counterparts. CD27+ and CD27− developing B cells show similar immunoglobulin heavy chain gene usage with low levels of mutations, suggesting that CD27+ developing B cells are distinct from mutated memory B cells. Despite these similarities, CD27+ developing B cells differ from CD27− developing B cells by their increased expression of LIN28B, a transcription factor associated with the fetal lymphoid lineages of mice. Furthermore, CD27+ pro-B cells efficiently generate IgM+IgD+ immature/transitional B cells in vitro. Our observations suggest that CD27 expression during B-cell development identifies a physiologic state or lineage for human B-cell development distinct from the memory B-cell compartment.</p><p>Regarding B-cell repertoire, due to the random recombination of immunoglobulin V, D, and J gene segments during B-cell development, B cells are highly diversified in their antigen specificity. Through their specific B-cell antigen receptors (BCRs), B cells recognize foreign (and self-) antigens, and present these antigens to cognate T cells to elicit/establish humoral responses, such as germinal centers, immunological memory, and long-lasting circulating antibodies. Some bacteria and viruses escape the host’s immune system by mimicking host antigens, as B cells that recognize shared epitopes on self- and foreign antigens may provide protection against such pathogens; however, these B cells are normally eliminated by tolerance mechanisms during development. The extent of tolerization manifest among human B cells that recognize both self- and foreign antigens is unknown. Here, I and my colleagues use an efficient single B-cell culture method and multiplexed antigen-binding assays to determine the specificity of about 2,300 clonal IgG antibodies produced by the progeny of single transitional and mature B cells. We show that in healthy individuals, half of the self-reactive B cells crossreact with foreign antigen, and that the frequencies of crossreactive B cells decrease by half between the transitional and mature B-cell stages, indicating that a substantial fraction of foreign specificities is lost by the second tolerance mechanisms. In SLE patients, who show defective peripheral tolerance, frequencies of crossreactive B cells are unchanged between the B-cell stages. The crossreactive, mature B cells in SLE patients show distinct reactivity to foreign antigens. We propose that activating forbidden B cells may be a good strategy for protection against host-mimicking pathogens if we can control tolerance. </p><p>Activated B cells can present antigen to T cells, as well as differentiate into memory B cells and plasma cells. Indeed, activated B cells express high levels of MHCII and are considered to be professional antigen presenting cells (APC), along with dendritic cells and macrophages. APC can be used to discover the epitopes targeted in T-cell responses; T cells are co-cultured with autologous APC in the presence of antigens and T-cell responses are evaluated. With numerous epitope candidates, mapping T-cell epitopes requires large numbers of APC; the availability of APC in blood is a limiting component and leukapheresis is often required. Since B cells can be expanded in vitro more easily than other APC, they represent a solution for the challenge of isolating adequate numbers of APC from blood in order to determine T-cell antigen specificity. I modified our single B-cell culture to support efficient activation and proliferation of both naïve and memory human B cells for the purpose of generating large numbers of autologous APC. Briefly, naïve or memory B cells recovered from blood are cultured with recombinant human IL-2, IL-4, IL-21, and BAFF on CD154+ feeder cells; this culture supports extensive B-cell proliferation, with approximately 103 fold increases following 8 days in culture, and 106 fold increases when cultures are split and cultured for 8 more days. The capacity for continued proliferation is stable for at least another week. In culture, a significant fraction of naïve B cells undergo isotype switching and terminally differentiate into plasmacytes. Culture-derived (CD) B cells are readily cryopreserved, and when recovered, retain their ability to proliferate and differentiate. Significantly, proliferating CD B cells express high levels of MHCII, CD80, and CD86. I have examined the APC function of CD B cells and found that they present both allo- and microbial antigens to autologous T cells with comparable efficiency to PBMC. Moreover, I am able to activate and expand antigen-specific memory B cells; these cultured cells are highly effective in presenting antigen to T cells. This culture method provides a platform for studying the BCR and TCR repertoires within a single individual.</p> / Dissertation
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Nouvelles approches méthodologiques pour l'obtention d'anticorps humains monoclonaux / New methods to produce human monoclonal antibodiesAit Mebarek, Mazhoura 28 November 2012 (has links)
Les anticorps monoclonaux représentent aujourd’hui un outil de choix en thérapeutique et en diagnostic. Les anticorps thérapeutiques sont des biomédicaments en plein essor depuis les années 1970 et représentent 10% du marché des produits pharmaceutiques. Les anticorps monoclonaux sont utilisés dans divers domaines : en cancérologie, pour lutter contre les maladies auto-immunes ou en infectiologie. Le nombre des anticorps monoclonaux en développement ne cesse d’augmenter. Les premiers anticorps monoclonaux utilisés en thérapie étaient d’origine murine et leur administration à l’Homme est susceptible de déclencher des effets secondaires. De nouveaux anticorps visant à limiter voir faire disparaitre ces effets indésirables tels que d’abord les anticorps chimériques, puis les anticorps humanisés et enfin les anticorps totalement humains ont été développés. 9 anticorps totalement humains sont actuellement sur le marché et d’autres sont en cours de développement. Le phage display, les souris transgéniques et l’utilisation de lymphocytes B humains sont les trois stratégies mises en œuvre pour produire des anticorps totalement humains. L’utilisation des lymphocytes B humains, peu étudiée à cause d’un faible rendement et de problèmes de stabilité, a connu ces dernières années un regain d’intérêt grâce à l’immortalisation virale par le virus Epstein-Barr et à la découverte de myélomes humains. Dans ce contexte, l’objectif de mon projet de thèse a été la production d’anticorps monoclonaux humains à partir de lymphocytes B humains. Pour ce faire, deux approches basées sur l’immortalisation virale par le virus Epstein-Barr couplée ou non à une immortalisation cellulaire par des myélomes ont été mises en œuvre. La première approche utilise des lymphocytes B mémoires isolés de sang périphérique de donneurs infectés ou vaccinés. L’entérotoxine B de Staphylococcus aureus (SEB) a été utilisée comme modèle.La deuxième approche implique une immunisation in vitro de lymphocytes B naïfs extraits de sang périphérique. Cette stratégie pourrait permettre la production d’anticorps humains contre des antigènes pour lesquels il n’existe pas de donneurs infectés ou vaccinés. Deux modèles, le peptide N-terminal de la neurotoxine A de Clostridium Botulinium A (BoNT/A) et la protéine de fusion ZZTat101, comportant le domaine ZZ de Staphylococcus aureus lié covalemment à la protéine transactivatrice Tat du virus de l’immunodéficience humaine VIH-1, ont été employés. Nous avons réussi à obtenir des IgMs dirigés contre la neurotoxine Clostridium Botulinium A, ainsi que des IgMs (et peut-être des IgGs) dirigés contre la protéine Tat. L’immortalisation par Epstein-Barr, nous a permis d’isoler 7 lignées de lymphocytes immortalisés sécrétant des anticorps IgMs anti-TBA-Nter humains. L’immunisation in vitro produisant essentiellement des IgMs, la possible production d’IgGs après stimulation par la protéine ZZTat101 se révèle un résultat très intéressant. Nous avons montré que la production d’anticorps par ZZTat101 impliquait les 7 cystéines, la région 22-57 et la liaison aux héparanes sulfates de Tat. / The number of monoclonal antibodies used as drug or under clinical investigation increases rapidly. The first murine monoclonal antibodies (mAbs) used in therapy induces human anti-mouse antibodies (HAMAs) when administered to patients. Such HAMAs hamper the therapeutic efficacy of mAbs and induce side effects. To limit these effects, new antibodies were developed during the, last 30 years. Chimeric, humanized and fully human antibodies were engineered. The use of human monoclonal antibodies (hAbs) appears ideal to solve the problem of HAMAs. Nowadays 9 fully human antibodies are available and others are evaluated in clinical trials or currently investigated in research labs. Three methods exist to produce fully human antibodies: the phage display, the transgenic mice and the use of human B lymphocytes. The majority of fully human antibodies resulted from the phage display and the transgenic mice methods. The use of human B lymphocytes is less investigated due to a poor yield and stability problems. These last years, the immortalization process, thanks to the involvement of the Epstein-Barr virus and human myeloma, induced a rise of interest for human B lymphocytes. In this context we decided to develop fully human monoclonal antibodies using human B lymphocytes through immortalization using the Epstein-Barr virus followed or not by an immortalization with a human/mouse heteromyeloma HM. The first approach is based on hAbs production from peripheral blood memory B lymphocytes isolated from infected or vaccinated donors. The Staphylococcus aureus enterotoxine B (SEB) was used as a model. Memory B lymphocytes were purified and cultured in the presence of Epstein-Barr virus (EBV). The transformation of memory B lymphocytes by EBV allowed the generation of immortalized B lymphocytes lines producing IgGs antibodies directed against SEB. We succeeded in isolating 6 EBV-immortalized memory B lymphocytes lines secreting anti-SEB IgGs antibodies. After many attempts to immortalize EBV immortalized memory B lymphocytes lines secreting anti-SEB antibodies with myeloma, the fusion of a EBV immortalized memory B lymphocytes with the human/mouse heteromyeloma HM led to an hybridoma. Unfortunately this hybridoma has rapidly lost its capacity to secrete d’IgGs anti-SEB. In the second approach the hAbs production implies the in vitro immunization of peripheral blood naïve lymphocytes. This strategy could allow the hAbs production against antigens for which no infected or vaccinated donors may be available. The Clostridium Botulinum neurotoxin A (BoNT/A), the most powerful toxin, and its N-terminal peptide (TBA-Nter) or the fusion protein ZZTat101 were used as models. ZZTat101 is a fusion between the ZZ domain of Staphylococcus aureus and the Tat protein of the human immunodeficiency virus HIV-1. Monocytes, B lymphocytes and T lymphocytes were isolated from human PBMC depleted of Natural killer. These cells were tools to develop efficient in vitro immunization protocols. IgMs directed against TBA-Nter and also IgMs (and possibly IgGs) directed against Tat were obtained. The use of the Epstein-Barr virus induced 7 EBV immortalized lines secreting anti-TBA-Nter IgMs antibodies. Unfortunately, after fusion with the heteromyeloma HM no hybridoma was isolated against TBA-Nter and Tat. The ZZTat101 mechanism involved on humoral response was studied, showing that the 7 cysteines, the region 22-57 and the ability of Tat to bind heparane sulfate are necessary to trigger the humoral response.
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