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IFN-α/β Induction by dsRNA and Toll-Like Receptors Shortens Allograft Survival Induced by Costimulation Blockade: A DissertationThornley, Thomas B. 23 October 2006 (has links)
Costimulation blockade protocols are promising alternatives to the use of chronic immunosuppression for promoting long-term allograft survival. However, the efficacy of costimulation blockade-based protocols is decreased by environmental insults such as viral infections. For example, lymphocytic choriomeningitis virus (LCMV) infection at the time of costimulation blockade treatment abrogates skin allograft survival in mice. In this dissertation, we test the hypothesis that viruses shorten allograft survival by activating the innate immune system through pattern-recognition receptors (PRRs), such as toll-like receptors (TLRs).
To investigate the role of innate immunity in shortening allograft survival, costimulation blockade-treated mice were co-injected with TLR2 (Pam3Cys), TLR3 (polyinosinic:polycytidylic acid, poly(I:C)), TLR4 (lipopolysaccharide, LPS), or TLR9 (CpG DNA) agonists, followed by transplantation with skin allografts 7 days later. Costimulation blockade prolonged skin allograft survival that was shortened in mice coinjected with TLR agonists. To investigate the underlying mechanisms of this observation, we used synchimeric mice, which circulate trace populations of anti-H2b transgenic alloreactive CD8+ T cells. In synchimeric mice treated with costimulation blockade, co-administration of all four TLR agonists prevented deletion of alloreactive CD8+ T cells. These alloreactive CD8+ T cells 1) expressed the proliferation marker Ki-67, 2) upregulated CD44, and 3) failed to undergo apoptosis. We also demonstrate that costimulation blockade-treated CD8α-deficient mice exhibit prolonged allograft survival when co-injected with LPS. These data suggest that TLR agonists shorten allograft survival by impairing the apoptosis of alloreactive CD8+T cells.
We further delineate the mechanism by which TLR agonists shorten allograft survival by demonstrating that LPS and poly(I:C) fail to shorten allograft survival in IFNRI- deficient mice. Interestingly, the ability of poly(I:C) to more potently induce IFN-α/β than LPS correlates with its superior abilities to shorten islet allograft survival and induce allo-specific CTL activity as measured by an in vivo cytotoxicity assay. The ability to shorten allograft survival and induce IFN-α/β is a TLR-dependent process for LPS, but is a TLR-independent process for poly(I:C). Strikingly, the injection of IFN-β impairs alloreactive CD8+T cell deletion and shortens allograft survival, similar to LPS and poly(I:C). These data suggest that LPS and poly(I:C) shorten allograft survival by inducing IFN-α/β through two different mechanisms.
Finally, we present data showing that viruses (LCMV, Pichinde virus, murine cytomegalovirus and vaccinia virus) impair alloreactive CD8+T cell deletion and shorten allograft survival, in a manner comparable to LPS and poly(I:C). Similar to LPS, LCMV and MCMV exhibit an impaired ability to shorten allograft survival in MyD88-deficient mice. These data suggest that the MyD88 pathway is required for certain viruses and TLR-agonists to shorten allograft survival.
In this dissertation, we present data supporting an important role for TLRs and IFN- α/β in shortening allograft induced by costimulation blockade. Our findings suggest that targeting these pathways during the peri-transplant period may enhance the efficacy of costimulation blockade protocols in the clinic.
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Two Distinct Modes of Signaling by Vascular Endothelial Growth Factor C Guide Blood and Lymphatic Vessel Patterning in Zebrafish: A DissertationVillefranc, Jacques A. 19 August 2011 (has links)
Vascular Endothelial Growth Factor Receptor-3 (VEGFR3/Flt4) and its ligand Vegfc are necessary for development of both blood and lymphatic vasculature in vertebrates. In zebrafish, Vegfc/Flt4 signaling is essential for formation of arteries, veins, and lymphatic vessels. Interestingly, Flt4 appears to utilize distinct signaling pathways during the development of each of these vessels. To identify components of this pathway, we performed a transgenic haploid genetic screen in zebrafish that express EGFP under the control of a blood vessel specific promoter. As a result, we indentified a mutant allele of vascular endothelial growth factor c (vegfc), vegfcum18. vegfcum18 mutants display defects in vein and lymphatic vessel development but normal segmental artery (SeA) formation. Characterization of this allele led to the finding that the primary defect in vegfcum18 mutants was a general failure in vein and lymphatic vessel sprouting. Further genetic and biochemical analysis of this mutant revealed profound paracrine defects, which likely result in the observed loss of lymphatic and venous structures. Furthermore, double mutant analysis demonstrated that defects during SeA formation in vegfcum18 mutants were masked by inputs from the Vegfa signaling pathway. Endothelial cell autonomous expression of vegfcum18 induced angiogenic effects on blood vessels while endothelial cells lacking vegfc displayed defects in tip cell occupancy, suggesting a cell autonomous-autocrine role for Vegfc during developmental angiogenesis. Finally, we present genetic evidence that links processing of Vegfc by Furin during the formation of lymphatics in zebrafish. Together the data presented here suggest two discrete modes of signaling during blood and lymphatic vessel development, thus implying that regulation of Vegfc secretion and processing may play a pivotal role in the formation of these distinct vessel types in zebrafish.
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Targeting the Histone Acetyl-Transferase, RTT109, for Novel Anti-Fungal Drug Development: A DissertationLopes da Rosa-Spiegler, Jessica 03 May 2012 (has links)
Discovery of new antifungal chemo-therapeutics for humans is limited by the large degree of conservation among eukaryotic organisms. In recent years, the histone acetyl-transferase Rtt109 was identified as the sole enzyme responsible for an abundant and important histone modification, histone H3 lysine 56 (H3K56) acetylation. In the absence of Rtt109, the lack of acetylated H3K56 renders yeast cells extremely sensitive to genotoxic agents. Consequently, the ability to sustain genotoxic stress from the host immune system is crucial for pathogens to perpetuate an infection. Because Rtt109 is conserved only within the fungal kingdom, I reasoned that Rtt109 could be a novel drug target.
My dissertation first establishes that genome stability provided by Rtt109 and H3K56 acetylation is required for Candida albicans pathogenesis. I demonstrate that mice infected with rtt109 -/- cells experience a significant reduction in organ pathology and mortality rate. I hypothesized that the avirulent phenotype of rtt109 -/- cells is due to their intrinsic hypersensitivity to the genotoxic effects of reactive oxygen species (ROS), which are utilized by phagocytic cells of the immune system to kill pathogens. Indeed, C. albicans rtt109 -/- cells are more efficiently killed by macrophages in vitro than are wild-type cells. However, inhibition of ROS generation in macrophages renders rtt109 -/- and wild-type yeast cells equally resilient to killing.
These findings support the concept that ability to resist genotoxic stress conferred by Rtt109 and H3K56 acetylation is a virulence factor for fungal pathogens and establish Rtt109 as an opportune drug- target for novel antifungal therapeutics.
Second, I report the discovery of a specific chemical inhibitor of Rtt109 catalysis as the initial step in the development of a novel antifungal agent. We established a collaboration with the Broad Institute (Cambridge, MA) to perform a high-throughput screen of 300,000 compounds. From these, I identified a single chemical, termed KB7, which specifically inhibits Rtt109 catalysis, with no effect on other HAT enzymes tested. KB7 has an IC50 value of approximately 60 nM and displays noncompetitive inhibition regarding both acetyl-coenzyme A and histone substrates. With the genotoxic agent camptothecin, KB7 causes a synergistic decrease in C. albicans growth rate. However, this effect is only observed in an efflux-pump mutant, suggesting that this compound would be more effective if it were better retained intracellularly. Further studies through structure-activity relationship (SAR) modifications will be conducted on KB7 to improve its effective cellular concentration.
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Respiratory Syncytial Virus (RSV) Induces Innate Immunity through Toll-Like Receptors and Acquired Immunity via the RSV G Protein: A DissertationMurawski, Matthew R. 22 July 2009 (has links)
Respiratory syncytial virus (RSV) causes a common infection that is associated with a range of respiratory illnesses from common cold-like symptoms to serious lower respiratory tract illnesses such as pneumonia and bronchiolitis. RSV is the single most important cause of serious lower respiratory tract illness in children < 1 year of age. Host innate and acquired immune responses activated following RSV infection have been suspected as contributing to RSV disease. Toll-like receptors (TLRs) activate innate and acquired immunity and are candidates for playing key roles in the host immune response to RSV. Leukocytes express TLRs including TLR2, TLR6, TLR3, TLR4, and TLR7 that can potentially interact with RSV and promote immune responses following infection. Using knockout mice, we have demonstrated that TLR2 and TLR6 signaling in leukocytes can activate innate immunity against RSV by promoting TNF-α, IL-6, CCL2 (MCP-1), and CCL5 (RANTES) production. As previously noted, TLR4 also contributed to cytokine activation (71, 90). Furthermore, we demonstrated that signals generated following TLR2 and TLR6 activation were important for controlling viral replication in vivo. Additionally, TLR2 interactions with RSV promoted neutrophil migration and dendritic cell activation within the lung. Collectively, these studies indicate that TLR2 is involved in RSV recognition and subsequent innate immune activation and may play a role in modulating acquired immune responses through DCs.
Despite the fact that RSV is the single most important cause of infant upper respiratory tract disease, there are no licensed vaccines available to prevent RSV disease. We have developed a virus-like particle (VLP) vaccine candidate for RSV. The VLP is composed of the NP and M proteins of Newcastle disease virus (NDV) and a chimera protein containing the cytoplasmic and transmembrane domains of the NDV HN protein and the ectodomain of the human RSV G protein (H/G). BALB/c mice immunized with 10 or 40 μg total VLP-H/G protein by intraperitoneal or intramuscular inoculation stimulated antibody responses to G protein as good as or better than comparable amounts of UV-inactivated RSV. Furthermore, VLP-H/G induced robust CTL responses in vaccinated animals. Immunization with two or even a single dose of these particles resulted in the complete protection of BALB/c mice from RSV replication in the lungs. Upon RSV challenge of VLP-H/G immunized mice, no enhanced pathology in the lungs was observed, although lungs of mice immunized in parallel with formalin-inactivated RSV (FI-RSV) showed the significant pathology that has been previously observed with FI-RSV vaccination. Thus, the VLP-H/G candidate vaccine was immunogenic in BALB/c mice and prevented replication of RSV in murine lungs with no evidence of immunopathology. These data support further development of virus-like particle vaccine candidates for RSV.
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The Role of Rip2 Protein in the Nod Mediated Innate Immune Response: A DissertationYang, Yibin 16 April 2010 (has links)
The Rip2 kinase contains a caspase recruitment domain (CARD) and has been implicated in the activation of the transcriptional factor NF-кB downstream of Nod-like receptors. However, how Rip2 mediates innate immune responses is still largely unclear. We show that Rip2 and IKK-γ become stably polyubiquitinated upon treatment of cells with the Nod2 ligand, muramyl dipeptide. We demonstrate a requirement for the E2 conjugating enzyme Ubc13, the E3 ubiquitin ligase Traf6 and the ubiquitin activated kinase Tak1 in Nod2-mediated NF-кB activation. We also show that M. tuberculosisinfection stimulates Rip2 polyubiquitination. Collectively, this study revealed that the Nod2 pathway is ubiquitin regulated and that Rip2 employs a ubiquitin-dependent mechanism to achieve NF-кB activation.
We also demonstrate that intraphagosomal M. tuberculosis stimulates the cytosolic Nod2 pathway. We show that upon Mtb infection, Nod2 recognition triggers the expression of type I interferons in a Tbk1- and Irf5-dependent manner. This response is only partially impaired by the loss of Irf3 and therefore, differs fundamentally from those stimulated by bacterial DNA, which depends entirely on this transcription factor. This difference appears to result from the unusual peptidoglycan produced by mycobacteria, which we show is a uniquely potent agonist of the Nod2/Rip2/Irf5 pathway. Thus, the Nod2 system is specialized to recognize bacteria that actively perturb host membranes and is remarkably sensitive to Mycobacteria, perhaps reflecting the strong evolutionary pressure exerted by these pathogens on the mammalian immune system.
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Pathogenesis of the <em>Helicobacter</em> Induced Mucosal Disease: A DissertationStoicov, Calin 17 June 2010 (has links)
Helicobacter pylori causes chronic gastritis, peptic ulceration and gastric cancer. This bacterium is one of the most prevalent in the world, but affects mostly the populations with a lower socioeconomical status. While it causes gastric and duodenal ulcers in only 20% of infected patients, less then 1% will develop gastric adenocarcinoma. In fact, H. pylori is the most important risk factor in developing gastric cancer. Epidemiological studies have shown that 80% of gastric cancer patients are H. pylori positive. The outcome of the infection with this bacterium depends on bacterial factors, diet, genetic background of the host, and coinfection with other microorganisms. The most important cofactor in H. pylori induced disease is the host immune response, even though the exact mechanism of how the bacterium is causing disease is unknown.
The structural complexity of Helicobacter bacteria makes us believe that different bacterial factors interact with different components of the innate immunity. However, as a whole bacterium it may need mainly the TLR2 receptor to trigger an immune response. The type of adaptive immunity developed in response to Helicobacter is crucial in determining the consequences of infection. It is now known for decades that a susceptible host will follow the infection with a strong Th1 immune response. IFNγ, IL-12, IL-1β and TNF-α are the key components of a strong adaptive Th1 response. This is further supported by our work, where deficient T-bet (a master regulator for Th1 response) mice were protected against gastric cancer, despite maintaining an infection at similar levels to wild type mice. On the other hand, a host that is resistant to Helicobacter develops an infection that is followed by a Th2 response sparing the mucosa from severe inflammation. Human studies looking at single nucleotide polymorphism of cytokines, like IL-1β, IL-10 and TNF-α have clearly demonstrated how genotypes that result in high levels of IL-1β and TNF-α, but low IL-10 expression may confer a 50-fold higher risk in developing gastric cancer.
The outcome of Helicobacter infection clearly relies on the immune response and genetic background, however the coinfection of the host with other pathogens should not be ignored as this may result in modulation of the adaptive immunity. In studying this, we took advantage of the Balb/C mice that are known to be protected against Helicobacter induced inflammation by mounting a strong Th2 polarization. We were able to switch their adaptive immunity to Th1 by coinfected them with a T. gondii infection (a well known Th1 infection in mice). The dual infected mice developed severe gastritis, parietal cell loss and metaplastic changes. These experiments have clearly shown how unrelated pathogens may interact and result in different clinical outcomes of the infected host.
A strong immune response that results in severe inflammation will also cause a cascade of apoptotic changes in the mucosa. A strict balance between proliferation and apoptosis is needed, as its disruption may result in uncontrolled proliferation, transformation and metaplasia. The Fas Ag pathway is the leading cause of apoptosis in the Helicobacter-induced inflammation. One mechanism for escaping Fas mediating apoptosis is upregulation of MHCII receptor. Fas Ag and MHCII receptor interaction inhibits Fas mediated apoptosis by an impairment of the Fas Ag receptor aggregation when stimulated by Fas ligand. Because H. pylori infection is associated with an upregulation of the MHCII levels on gastric epithelial cells, this indeed may be one mechanism by which cells escape apoptosis.
The link between chronic inflammation and cancer is well known since the past century. Helicobacter infection is a prime example how a chronic inflammatory state is causing uncontrolled cell proliferation that results in cancer. The cell biology of “cancer” is regarded not as an accumulation of cells that divide without any control, but rather as an organ formed of cancer stem cells, tumor stromal support cells, myofibroblasts and endothelial cells, which function as a group. The properties of the cancer stem cells are to self-renew and differentiate into tumor cells thus maintaining the tumor grow, emphasizing that a striking similarity exists between cancer stem cells and tissue stem cells.
We looked into what role would BMDCs play in chronic inflammation that causes cancer. Using the mouse model of Helicobacter induced adenocarcinoma we discovered that gastric cancer originates from a mesenchymal stem cell coming from bone marrow. We believe that chronic inflammation, in our case of the stomach, sets up the perfect stage for bone marrow stem cells to migrate to the stomach where they are exposed to inflammatory stimuli and transform into cancer stem cells. One of the mechanism by which the MSC migrate to the inflammation site is the CXCR4/SDF-1 axis.
Our work sheds new light on Helicobacter induced gastric cancer pathogenesis. I hope that our findings will promote the development of new therapies in the fight against this deadly disease.
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Endocytosis, Phagocytosis, and Innate Immune Responses: A DissertationSt. Pierre, Christine A. 13 July 2010 (has links)
In this dissertation, the roles of endocytosis and phagocytosis pathways in a variety of clinically relevant scenarios were examined. These scenarios include antibody-mediated internalization of cell surface proteins, titanium wear-particle uptake in failed joint replacements, and polymeric microparticle uptake and immune responses for drug delivery or adjuvant use.
The use of antibodies specific for cell surface proteins has become a popular method to deliver therapeutics to target cells. As such, it is imperative to fully understand the ability of antibodies to mediate internalization and endosomal trafficking of the surface protein that it recognizes, so that drug delivery can be optimized. By comparing the internalization and endosomal localization of two different antibody-bound proteins, the transferrin receptor (TfR) and rabies G, we have found that there is a specific antibody-mediated internalization pathway that occurs when an antibody binds to a cell surface protein. Interestingly, the internalization pathway induced by antibody binding is different than that seen with recycling receptor internalization after ligand binding. This may have broad implications for the future development of antibody-based therapeutics.
Joint replacement failure is a major clinical problem. Studies have indicated that a large amount of metal and polyethylene wear debris is found in the synovial membrane and tissue surrounding failed replacements. Through examination of the immune response following uptake of titanium particles, our results suggest that titanium wear-particle induced inflammation and subsequent joint replacement failure may be due to activation of the NLRP3 inflammasome, leading to increased IL-1ß secretion and IL-1 associated signaling. These findings introduce IL-1 as a target for potential therapeutics for patients exhibiting significant inflammation.
Polymeric microparticles have been widely used in a variety of therapeutic applications, including drug delivery and vaccine adjuvants. It is essential to understand the ability of such particles to either activate or inhibit an immune response following uptake. Through comparison of particles with varying surface morphology, we have determined that particles with regions of high surface curvature (budding) are more immunogenic than particles with low surface curvature (spherical). Budding particles were more rapidly phagocytosed and induced higher levels of the inflammasome-associated cytokine, IL-1ß, when exposed to mouse macrophages. Additionally, budding particles induced a more rapid neutrophil response in vivo, when compared to spherical particles. These findings have broad implications for the development of future targeting vehicles for delivery of vaccines, drugs, proteins, and siRNA therapeutics.
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CD4+ T Cell Responses: A Complex Network of Activating and Tolerizing Signals as Revealed by Gene Expression Analysis: A DissertationBrown, David Spaulding 20 September 2005 (has links)
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.
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T Cells Aid in Limiting Pathogen Burden and in Enhancing B1 and B2 Cell Antibody Responses to Membrane Glycolipid and the Surface Lipoprotein Decorin-Binding Protein A during Borrelia burgdorferi Infection: A DissertationMarty-Roix, Robyn Lynn 15 June 2010 (has links)
Murine infection by the Lyme disease spirochete, B. burgdorferi, results in the generation of pathogen-specific antibody that can provide protection against Lyme disease, but the cells involved in this response are poorly characterized. T cells are not required for generating a protective antibody response to B. burgdorferi infection, but their exact role in providing protection against tissue colonization had not been previously determined. We found that TCRβxδ;-/- mice were susceptible to high pathogen loads and decreased antibody titers, but inhibition of CD40L-dependent interactions resulted in partial protection suggesting that a portion of the help provided by T cells was not dependent on CD40L-CD40 interactions between T and B cells. RAG1-/- mice reconstituted with either un-fractionated or B1-enriched peritoneal cells from previously infected mice generated B. burgdorferi-specific antibody, and upon spirochetal challenge suffered significantly lower levels of pathogen load in the joint and heart. Peritoneal cells from previously infected TCRβxδ-/- mice or B2-enriched or B1-purified peritoneal cells conferred little to only moderate protection, suggesting T cells play an important role in protection against spirochetal infection the joint. Consistent with this, T cells from previously infected donor mice, when transferred with B1 or B2 cells into RAG1-/- mice, generated increased antibody titers and were capable of diminishing bacterial burden in the joint and heart. A previously identified class of protective antibody is directed against the spirochetal surface lipoprotein DbpA, and we found that DbpA is a prominent protein antigen recognized by RAG1-/- mice reconstituted with B1-enriched peritoneal cells. Additionally, we found that mice reconstituted with B1 cells also make antibody directed towards the spirochetal glycolipid antigen, BbGL-IIc, which is recognized by Vα14iNKT cells. Consistent with the idea that T cells are important in providing protection against spirochetal infection, RAG1-/- mice reconstituted with B1 and T cells generated a more robust response against DbpA and BbGL-IIc. These results support the hypothesis that T cells act with B1 cells in a CD40L-independent manner to promote the production of antibodies that play an important role in protection of the joint from spirochetal infection.
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Dynamics of Erythropoietic Survival Pathways In Vivo: A DissertationKoulnis, Miroslav 11 July 2011 (has links)
Erythropoiesis maintains stable tissue oxygenation in the basal state, while accelerating red cell production in anemia, blood loss or high altitude. The principal regulator of erythropoiesis is the hormone erythropoietin (Epo). In response to hypoxic stress, Epo can increase a 1000-fold, driving erythropoietic rate by up to 10-fold. It’s been suggested that survival pathways activated by the Epo receptor (EpoR) underlie its regulation of erythropoietic rate. A number of apparently redundant EpoR survival pathways were identified in vitro, raising the possibility of their functional specialization in vivo.
Here I assessed the roles of three survival pathways activated by EpoR in erythroblasts in-vivo: the suppression of cell-surface Fas and FasL, the suppression of the pro-apoptotic regulator Bim, and the induction of the anti-apoptotic regulator Bcl-xL. I used the novel CD71/Ter119 flow-cytometric method of identifying erythroblast maturation stages in vivo to measure these apoptotic pathways in fetal liver and adult erythropoietic tissues. I found that these pathways differ markedly in their regulation of erythropoietic rate.
Using mouse genetic models, I found that apoptosis mediated by interaction between erythroblasts that co-express cell-surface Fas and FasL plays a key autoregulatory role in stabilizing the size of the erythroblast pool in the basal state. Further, mice mutant for Fas or FasL showed a delayed erythropoietic response to hypoxia or high Epo. This suggests that Fas and FasL accelerate the stress response by providing an apoptotic ‘cell reserve’ that can be rescued by Epo in stress.
I also examined the in-vivo behavior of two cell-intrinsic apoptotic regulators, Bcl-xL and Bim, previously unexamined in stress. The induction of Bcl-xL was rapid but transient, whilst the suppression of Bim was slower but persistent. My data suggest that Bcl-xL is a key mediator of EpoR’s anti-apoptotic signal very early in the stress response, before Bim and Fas are suppressed. Bcl-xL adaptation to high Epo occurs through inhibition of Stat5 activation, and resets it for the next acute stress.
My findings suggest that in vivo, Epo regulates erythropoietic rate through erythroblast apoptosis, and that various apoptotic regulators play distinct and unique roles in this process. My work provides new molecular insights into erythropoiesis that are relevant to cytokine biology and to clinical approaches of disease treatment.
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