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- Zhang, Lu, 1987-
(author)
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IgG3 Complements IgM in the Complement-Mediated Regulation of Immune Responses
- 2017
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Doctoral thesis (other academic/artistic)abstract
- An intact complement system is essential for the initiation of a normal antibody response. Antibodies can regulate their own production against the antigens that they are specific for. Both IgG3 and IgM are able to enhance the antibody response via complement. Here, we have compared the fate of OVA-TNP (ovalbumin-2,4,6-trinitrophenyl) administered intravenously to mice either alone or in complex with monoclonal IgG3 anti-TNP. IgG3-antigen complexes bind to marginal zone (MZ) B cells via complement receptors 1 and 2 (CR1/2) and are transported into splenic follicles. The majority (50% - 90%) of the antigens is deposited on follicular dendritic cells (FDC) and the antigen distribution pattern is strikingly similar to peripheral dendrites/processes of FDC already 2 h after immunization. The development of germinal centers (GC) induced by IgG3-antigen complexes is impaired in mice lacking CR1/2. Experiments on bone marrow chimeric mice show that CR1/2 expression on both MZ B cells and FDC is required for optimal IgG3-mediated enhancement of antibody responses. Complement factors C3 and C1q are essential for OVA-TNP delivery and deposition on splenic FDC. The production of IgG anti-OVA is abrogated in mice lacking CR1/2, C1q, and C3. Further, IgG3-antigen complexes dramatically upregulate the memory response against OVA-TNP by inducing OVA-specific memory cells. Besides small protein OVA, IgG3 can also upregulate humoral responses against large soluble keyhole limpet hemocyanin.To further study the role of MZ B-cells and CR1/2 in enhancement of antibody responses, a knock-in mouse strain, Cμ13, was used. IgM in this mouse strain is unable to activate complement due to a point mutation in the constant µ-heavy chain. Cμ13 mice have a higher proportion of MZ B cells, with higher CR1/2 expression, than wild-type mice. More IgG3-immune complexes are captured by MZ B cells and deposited on FDC in Cμ13 than in WT mice. In spite of this, IgG3 did not enhance the primary antibody response more efficiently in Cμ13 mice. The existence of endogenous IgM-mediated feedback regulation was suggested by the observation that GC development and antibody responses, after priming and boosting with suboptimal doses of SRBC, was lower in Cμ13 than in WT mice.
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| 2. |
- Banday, Viqar, 1984-
(author)
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Metab-Immune analysis of the non-obese diabetic mouse
- 2016
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Doctoral thesis (other academic/artistic)abstract
- Type 1A diabetes mellitus or T1D is a chronic disease characterized by T cell mediated destruction of the insulin producing β cells in the islets of Langerhans. The classical symptoms include high glucose levels in urine and blood, polyuria, and polydipsia. Complications associated with T1D include blindness, amputations, and end-stage renal disease, and premature death. The non-obese diabetic (NOD) mouse, first described in 1980, is widely used as a model organism for T1D. T1D disease in the NOD mouse shares a number of similarities to human T1D including dependence on genetic and environmental factors. More than 30 disease associated gene regions or loci (termed insulin dependent diabetes, or Idd, loci) have been associated with T1D development in NOD. For some of these Idds, the corresponding region in human has been linked to the development of T1D in human.T1D, both in humans and mice, is recognized as a T cell mediated disease. However, many studies have shown the importance of both the metabolome and the immune system in the pathogenesis of the disease. Appearance of autoantibodies in the serum of patients is the first sign of pathogenesis. However, molecular and cellular events precede the immune attack on the β-cell immunity. It has been shown that patients who developed T1D have an altered metabolome prior to the appearance of autoantibodies. Although much is known about the pathogenesis of T1D, the contribution of the environment/immune factors triggering the disease is still to be revealed. In the present study both metabolic and immune deviations observed in the NOD mouse was analyzed. Serum metabolome analysis of the NOD mouse revealed striking resemblance to the human metabolic profile, with many metabolites in the TCA cycle significantly different from the non-diabetic control B6 mice. In addition, an increased level of glutamic acid was of the most distinguishing metabolite. A detailed bioinformatics analysis revealed various genes/enzymes to be present in the Idd regions. Compared to B6 mice, many of the genes correlated to the metabolic pathways, showed single nucleotide polymorphism (SNP), which can eventually affect the functionality of the protein. A genetic analysis of the increased glutamic acid revealed several Idd regions to be involved in this phenotype. The regions mapped in the genetic analysis harbor important enzymes and transporters related to glutamic acid. In-vitro islet culture with glutamic acid led to increased beta cell death indicating a toxic role of glutamic acid specifically towards insulin producing beta cells.In the analysis of the immune system, B cells from NOD mice, which are known to express high levels of TACI, were stimulated with APRIL, a TACI ligand. This resulted in enhanced plasma cell differentiation accompanied with increased class switching and IgG production. NOD mice have previously been shown to react vigorously to T-dependent antigens upon immunization. In this study we confirmed this as NOD mice showed an enhanced and prolonged immune response to hen egg lysozyme. Thus, serum IgG levels were significantly increased in the NOD mice and were predominantly of the IgG1 subtype. Immunofluorescence analysis revealed increased number of germinal centers in the NOD mice. Transfer of purified B and T cells from NOD to an immune deficient mouse could reproduce the original phenotype as seen in the NOD mice. Collectively, this thesis has analyzed the metabolomics and immune deviations observed in the NOD mice.
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| 3. |
- Haraldsson, Katarina, 1958-
(author)
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Defining the genetics of systemic autoimmunity in mouse models of lupus
- 2008
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Doctoral thesis (other academic/artistic)abstract
- Systemic Lupus Erythematosus (SLE) is a chronic multi-organ autoimmune disease considered a prototype for autoantibody and immune complex-mediated tissue injury. Although autoantibodies against a wide diversity of self-antigens are characteristically found in this disease, an important hallmark is the presence of autoantibodies to nuclear antigens. Despite this common clinical feature, individual patients vary widely in the organ systems afflicted, disease severity, disease course, and response to treatment. These characteristics make clinical management of SLE challenging and highlight the need for effective and less toxic therapeutic interventions. Susceptibility to lupus has been shown in both human studies and mouse models to be dependent on genetic predisposition. Therefore, it is likely that knowledge of the genetic basis of SLE will be required before full understanding of SLE pathogenesis can be achieved. In this thesis, studies to define the genetic basis of lupus in an induced and two spontaneous models of the disease are presented. These studies encompass mapping, characterization of interval congenic mice, and cloning of the Lmb3 locus gene. In the first study, a genomewide mapping study was performed to define the genetic basis for resistance of the DBA/2 mice to mercury-induced autoimmunity. On chromosome 1, a single quantitative trait was linked with resistance to HgIA. These results linked the locus Hmr1 to a late stage of lupus with GN. Interval congenic mice are important tools to define and characterize the roles of different loci in lupus-like diseases. The second paper identifies the effect of NZB and NZW Lbw2 alleles on lupus susceptibility by using BWF1 mice with none, one or two copies of the lupus-predisposing NZB.Lbw2 locus. The lack of the NZB locus significantly reduced mortality, GN and B cell activation. IgM anti-chromatin levels in genome-wide mapping was linked only to Lmb2 and none of the known B cell hyperactivity-promoting genes were present in this location, which might indicate a novel B cell activation gene. The third study used reciprocal single locus interval-specific congenic mice to characterize the contribution of Lmb1-4 on the MRL-Faslpr and B6-Faslpr backgrounds. The Lmb3 locus on chromosome 7 was found to have the most prominent phenotype with clear effects on lymphoproliferation, GN and mortality. In the fourth paper the Lmb3 was cloned and shown to be a spontaneous nonsense mutation in the Coro1a gene that encodes an actin-binding and -regulatory protein. Upon further characterization, this genetic alteration was discovered to be a new lupus suppressing mutation that reduced T cell migration, activation, and survival. Our findings highlight the complexity of the genetics of lupus, and further suggest that genes involved in controlling the actin cytoskeleton might be potential targets for autoimmune therapeutics.
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| 4. |
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| 5. |
- Thyagarajan, Radha, 1986-
(author)
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Anomalies in humoral immunity in the NOD mouse : contribution to the progression of type 1 diabetes
- 2016
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Doctoral thesis (other academic/artistic)abstract
- The non-obese diabetic (NOD) mouse is widely used model Type 1 diabetes (T1D), a chronic inflammatory disease characterized by destruction of the insulin producing β cells in the islets of Langerhans by immune cells. The classical symptoms include increased glucose levels in urine and blood, frequent urination and enhanced thirst. The disease has a strong genetic component and is also influenced by the environment. NOD mice develop T1D spontaneously. The disease occurs in two phases; insulitis - the infiltration of immune cells in the islets of Langerhans and overt diabetes caused by the destruction of insulin producing β cells. Several disease associated gene regions or loci [termed insulin dependent diabetes (Idd) loci] have been associated with T1D development. Although, T1D is recognized as a T cell mediated disease in both mouse and man, many studies have shown the importance of B cells in the pathogenesis of the disease. Autoantibodies appear prior to islet infiltration and several molecular and cellular events precede this beta-cell autoimmunity. Although the pathogenesis of T1D is well characterized, less is known about the environmental and immunological factors that trigger the disease.In this thesis, we studied the contribution of B cell anomalies to the skewed immune response observed in the NOD mouse. In our studies covered in the thesis we observed that NOD mice display enhanced IgE in the serum already at one week of age. In addition, upon treatment of pre-diabetic NOD mice with anti-IgE antibodies, diabetes incidence was delayed. We hypothesize that the presence of IgE in the system may be explained due to enhanced class switching. Antibody feedback however, is an essential component of the immune response and can lead to either enhanced or dampened responses. Thus, increased IgE may provide positive feedback that might sustain an immune response. We also aimed to analyze the biological consequence of this feature. In vitro stimulation of B cells by the TACI ligand APRIL resulted in enhanced plasma cell differentiation accompanied with increased class switching and IgG production. In addition, TACI+ cells were observed in NOD germinal centers facilitating increased BAFF uptake and subsequent escape of low affinity antibody producing clones. NOD mice elicited an enhanced and prolonged immune response towards T-dependent antigens such as hen-egg lysozyme (HEL). Serum HEL-specific IgG level was significantly increased and was predominantly of the IgG1 isotype. Immunofluorescence analysis of NOD spleen revealed the presence of spontaneous germinal centers which others have perceived to provide a ready niche for the entry of naïve B cells that encountered novel antigen. Adoptive transfer experiments of purified B and T cells from NOD into NOD.Rag2-/- (NOD-RAG) mice illustrated the importance of B cell intrinsic defects in the reproduction of the original phenotype as observed in NOD.
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