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Negative Regulation of Type I Interferon Induction in Dendritic CellsLiu, Yi January 2011 (has links)
No description available.
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Effects of Toll-Like Receptors and Type I Interferon on Dendritic Cell Maturation and Activation of T CellsSimmons, Daimon P. January 2011 (has links)
No description available.
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Effect of Pharmacological Calcium Mobilization as a Co-signal Regulating IL-12 Production by Murine Dendritic CellsHuang, Emily Chi Ping 28 April 2014 (has links)
No description available.
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INTERACTIONS OF HISTOPLASMA CAPSULATUM YEASTS WITH HUMAN DENDRITIC CELLSGildea, Lucy Anne January 2000 (has links)
No description available.
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KLF2: A Kruppel like Family Transcription Factor in Myeloid Cells Negatively Regulates Th2 ResponseXiong, Ye January 2015 (has links)
No description available.
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THE USE OF A TEC KINASE INHIBITOR, IBRUTINIB, FOR THE DEVELOPMENT OF IMMUNOTHERAPIES AGAINST CANCER AND LEISHMANIASIS.Natarajan, Gayathri 10 November 2016 (has links)
No description available.
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Modulators of Dendritic Cells and B cells in LupusLee, Michael Hweemoon January 2019 (has links)
Systemic Lupus Erythematosus (SLE) is an autoimmune disease characterized by the production of autoantibodies directed against ubiquitous self-antigens, many of which are nuclear autoantigens like dsDNA and chromatin (Pisetsky, 2016), and by elevated type I interferons (IFN) (Hooks et al., 1979; Weckerle et al., 2011), a family of pro-inflammatory cytokines that have antiviral activity (Pestka et al., 2004). Microarray analysis of peripheral blood mononuclear cells (PBMC) from SLE patients discovered the increased expression of IFN-responsive genes that was named the IFN Signature (Baechler et al., 2003a; Bennett et al., 2003b; Crow et al., 2003). Genome wide association studies indicate a clear genetic component in lupus pathogenesis (Chung et al., 2011; SLEGEN et al., 2008) and murine models of SLE confirm genetic drivers of the disease (Morel, 2010; Morel et al., 2000). However, the concordance of SLE in monozygotic twins is only 30-40% (Connolly and Hakonarson, 2012), while the inc / Microbiology and Immunology
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Novel protocols to induce tolerance to solid organ transplantsChakhtoura, Marita January 2016 (has links)
Dendritic cells (DCs) are the sentinels of the immune system. They mature at the encounter of the appropriate stimuli or danger signals, which induce them to perform pro-inflammatory antigen presentation to naïve and memory T cells, resulting in inflammation. Remaining in an immature state however, DCs acquire a tolerogenic phenotype. When activated by TLR ligands, DCs undergo metabolic re-programming and switch to TBK1/IKKe/AKT-induced glycolysis at the early activation phase, which is sustained due to nitric oxide (NO)-mediated inhibition of mitochondrial metabolism at the later activation phase. Targeting DC activation in the view of promoting less activated or tolerogenic DCs could be an approach to reduce or abrogate inflammation in settings such as solid organ transplant rejection or in autoimmune diseases such as systemic lupus erythematosus (SLE). In this thesis, we present data pertaining to three different approaches for targeting DC activation including 1) the use of ethyl p / Microbiology and Immunology
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Regulation of type I interferons in murine dendritic cellsXu, Jun January 2014 (has links)
Conventional Dendritic cells (cDCs), a specialized group of immunological sentinels with tree-like or dendritic shapes, are critical for recognition of danger signals, presentation of antigens and control of a spectrum of innate and adaptive immune responses. Type I interferons (IFNs), as important danger signals, activate cDCs through the canonical type I IFN receptor signaling. Type I IFNs are the first line of host defense against viral infection by up-regulating IFN-stimulated genes (ISGs). However, there are circumstances in which the silencing of excessive type I IFNs could be beneficial to the host, such as IFN-dependent autoimmune diseases, gene therapy that uses viral vectors and transplantation. The role of type I IFNs in DC development, activation and antigen presentation function remains to be completely investigated. In this dissertation, we studied the regulation of Type I IFNs in murine DCs, both cDCs and plasmacytoid DCs (pDCs), and specifically we investigated the role of two molecules, Signal Transducer and Activator of Transcription 2 (STAT2) and Three prime Repair EXonuclease 1 (Trex1), in DC biology. Our research furthers our understanding of DC development, activation and function, and provides important data for the therapeutic application of modified DCs to induce immunological tolerance in gene therapy, IFN-dependent autoimmune diseases and transplantation. STAT2 is a nuclear transcription factor downstream of type I IFN receptor-mediated signaling, the role of which has been mostly explored in antiviral responses mediated by type I IFNs. However, the involvement of STAT2 in cDC activation and function such as cross-presentation remains hitherto unclear. We report that STAT2 is essential for murine cDC activation upon TLR3, -4, -7 and -9 stimulation. In the absence of STAT2, cDCs displayed impaired up-regulation of type I IFN response (costimulatory molecules and type I IFN-stimulated genes), and reduced inflammatory cytokine production when stimulated with TLR ligands. STAT2 was required in all of the DC responses to exogenous IFNα, suggesting that the canonical STAT1-STAT2 heterodimers are the major signaling transducers downstream of type I IFNs in DCs. Of interest, LPS-induced TNFα and IL6 production were reduced in STAT2-/- DCs but not in IFNAR1-/- DCs, suggesting a novel STAT2-dependent pathway mediated by LPS, bypassing type I IFN-receptor signaling. STAT2-deficient cDCs showed impaired cross-presentation leading to decreased CD8+ T cell response both in vitro and CTL killing in vivo, indicating that STAT2 is essential for TLR-induced cross-presentation. These results demonstrate that STAT2 is critical in the regulation of TLR-induced DC activation and cross-presentation, suggesting an essential role for STAT2 in anti-viral and anti-tumor immune responses. We also propose a novel regulatory function of STAT2 in the LPS response independent of type I IFN receptor signaling. Trex1 mutations are associated with a spectrum of type I IFN-dependent autoimmune diseases such as Aicardi-Goutières syndrome and systemic lupus erythematosus. Trex1 plays an essential role in preventing accumulation of excessive cytoplasmic DNA, avoiding cell-intrinsic innate DNA sensor activation and suppressing activation of both type I IFN-stimulated and IFN-independent antiviral genes. Trex1 also helps HIV escape cytoplasmic detection by DNA sensors. However, regulation of Trex1 in DC biology is lacking. We report that murine cDCs have high constitutive expression of Trex1 in vitro and in vivo in the spleen. In resting bone marrow-derived cDCs, type I IFNs up-regulate Trex1 expression via the canonical IFN receptor signaling pathway (STAT1-, STAT2-dependent). DC activation induced by TLR3, -4, -7 and -9 ligands also augments Trex1 expression through autocrine IFNß production and triggering of the IFN signaling pathway, while TLR4 ligand LPS also stimulates an early expression of Trex1 through an IFN-independent NFΚB-dependent signaling pathway. Furthermore, retroviral infection also induces Trex1 up-regulation in cDCs, as we found that a gene therapy HIV-1-based lentiviral vector induces significant Trex1 expression, suggesting that Trex1 may affect local and systemic administration of gene therapy vehicles. Our data indicate that Trex1 is induced in cDCs during activation upon IFN- and TLR- stimulation through the canonical IFN signaling pathway, and suggest that Trex1 may play a role in cDC activation during infection and autoimmunity. Finally, these results suggest that HIV-like viruses may up-regulate Trex1 to increase their ability to escape immunosurveillance. In order to dissect the role of Trex1 in DC functions, we compared DCs from Trex1-/- and wild-type mice. We report that Trex1 deficiency reduces absolute number of pDCs in BM but not in spleen of male over female mice. Furthermore, Trex1 deficiency preferentially represses Flt3L-induced DC development both in vitro and in vivo but not GM-CSF-dependent DC development, suggesting that Trex1 plays an indispensable role in Flt3L-induced DC development and GM-CSF may compensate the effect of Trex1 deficiency. This defect is only limited to male Trex1-/- DCs, and mimics the effect of mTOR inhibition. Furthermore, although Flt3L-induced Trex1-/- DCs expressed a type I IFN signature, they also exhibited decreased pDC development markers, indicating Trex1 regulates pDC development at the transcriptional level. Thus, we propose a novel and essential role of Trex1 in Flt3L-induced DC development, and the effect of Trex1 regulation is gender-dependent. Together, these findings enhance our understanding of regulatory roles of Type I IFNs in DC development, activation and function, supporting the beneficial role of STAT2/type I IFN axis in TLR-induced DC activation and cross-presentation. Our study in Trex1 reveals Trex1 induction by viral infection, type I IFNs and TLRs in DCs, and a new role of Trex1 in early development of Flt3L-induced DCs in a gender-dependent manner, whereby a balance between type I IFNs and Trex1 is important for DC activation and hemostasis. / Microbiology and Immunology
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Characterization of Dendritic Cells in the Bovine Mammary GlandMaxymiv, Nicolas George 24 January 2010 (has links)
Bacterial mastitis is a significant problem for the dairy industry. A vaccine against mastitis pathogens could potentially target dendritic cells (DC). While there has been some research describing bovine DC populations in-vitro, little is known about DC in mammary tissue. In this study, immunohistofluorescence was used to identify and localize bovine mammary DC. DC were found in alveoli, in epithelia, and in interalveolar tissue. Fluorescence-activated cell sorting (FACS) was used to characterize mammary DC as expressing CD11c, MHC-II, CD205, CD11b, and CD8α. FACS allowed us to distinguish DC (CD14lo) from macrophages (CD14hi). Two DC subsets, CD11a-, CD11alo, were evident in the mammary gland while an additional CD11ahi population was identified in the supramammary lymph node. After phagocytosis of bacterial components such as lipopolysaccharide (LPS), DC undergo a maturation process, in which they upregulate homing receptors, such as CCR7, and antigen presentation markers, including MHCII and CD80. A primary cell culture model was used to evaluate changes in transcription of CD80 and CCR7 after LPS stimulation. Cell cultures contained digested and Ficoll separated mammary tissue or supramammary lymph node tissue. While the presence of CCR7 and CD80 was confirmed, CD80 and CCR7 transcripts were not upregulated after LPS stimulation. Further, CD11c, CD14, MHCII, CD11b, CD11a, and CD205 protein levels, as assessed by FACS, were similar in LPS stimulated cultures and unstimulated controls. Overall, these studies provide a better understanding of mammary gland immunology, while potentially aiding in the development of novel DC based vaccines. / Master of Science
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