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Insights Into the Regulatory Requirements for T Follicular Helper Cell DevelopmentPowell, Michael D. 22 April 2019 (has links)
During the course of an immune response, CD4+ T helper cells differentiate into a number of subsets including: T helper 1 (TH1), TH2, TH17, and T follicular helper (TFH) populations. The functional diversity of CD4+ T effector cells results in a coordinated, pathogen-specific immune response. For example, the production of IFNγ by TH1 cells is vital for the clearance of intracellular pathogens, while TFH cell engagement with cognate B cells is required for germinal center (GC) formation and the generation of pathogen- and vaccine- induced antibody production. The development of CD4+ subsets is contingent on extracellular signals, in the form of cytokines, and downstream transcriptional networks responsible for promoting the unique gene expression profile for each subset while simultaneously suppressing alternative cell fates. However, the exact composition of, and stage-specific requirements for, these environmental cytokines and transcription factor networks in the governance of TFH cell differentiation remain incompletely understood. The work in this dissertation seeks to understand how cell-extrinsic cytokine signals and cell-intrinsic transcription factor activities are integrated to properly regulate TFH cell development. Here, we demonstrate that in response to decreased IL-2 and constant IL-12 signaling, T helper 1 (TH1) cells upregulate a TFH-like phenotype, including expression of the TFH lineage defining transcription factor Bcl-6. Intriguingly, our work established that signals from IL-12 were required for both the differentiation and function of this TFH-like population. Mechanistically, IL-12 signals are propagated through both STAT3 and STAT4, leading to the upregulation of the TFH associated genes Bcl6, Il21, and Icos, correlating with increased B cell helper activity. Conversely, exposure of these TFH-like cells to IL-7 results in the STAT5-dependent repression of Bcl-6 and subsequent inhibition of the TFH phenotype. Finally, we describe a novel regulatory mechanism wherein STAT3 and the Ikaros zinc finger transcription factors Ikaros and Aiolos cooperate to regulate Bcl-6 expression in these TFH-like cells. Collectively, the work in this dissertation significantly advances our understanding of the regulatory mechanisms that govern TFH cell differentiation, setting the basis for the rational design of novel immunotherapeutic strategies and increasingly effective vaccines. / Ph. D. / Specialized cells called T helper cells serve as a critical interface between the innate (first line of defense) and adaptive (specialized and long-term) immune systems. During the course of an infection, T helper cells are responsible for orchestrating the immune-mediated elimination of invading viruses, bacteria, and parasites. This wide breadth of functionality is achieved through the formation of distinct T helper subsets including T helper 1 (TH1), TH2, TH17, and T follicular helper (TFH) populations. Individual subsets have distinct developmental requirements and have unique functions within the immune system. For example, TFH cells are required for the production of effective antibodies that recognize invading pathogens, leading to their subsequent elimination. This naturally occurring process is the basis for a number of modern medical therapies including vaccination. Conversely, aberrant generation of antibodies that recognize host tissues can result in the onset of various autoimmune diseases including lupus, multiple sclerosis, and crohn’s disease. Due to the importance of TFH cells to human health, there is intense interest in understanding how these cells are formed. It is recognized that the generation of these therapeutically important immune cells is mediated by numerous cell-extrinsic andintrinsic influences, including proteins in their cellular environment called cytokines, and important proteins inside of the cell called transcription factors. However, as this is a complicated and multi-step process, many questions remain regarding the identity of these cytokines and transcription factors. The work in this dissertation seeks to understand how cellextrinsic cytokine signals and cell-intrinsic transcription factor activities are integrated to properly regulate TFH cell development. Collectively, this body of work significantly advances our understanding of the regulatory mechanisms that govern TFH cell differentiation, setting the basis for the rational design of novel immunotherapeutic strategies and increasingly effective vaccines.
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The Role of IkZF Factors in Mediating TH1/TFH Development and FlexibilityBharath Krishnan Nair, Sreekumar 24 January 2020 (has links)
The ability of cells within the adaptive immune system to develop into specialized subsets allow for a robust and tailored immune response in the advent of an infection or injury. Here, CD4+ T-cells are a crucial component within this system, with subsets such as TH1, TH2, TH17, TFH and TREG cells playing vital roles in propagating cell-mediated immunity. For example, TH1 cells are essential in combating intracellular pathogens such as viruses, while TFH cells communicate with B-cells to optimize antibody responses against an invading pathogen. The development (and functionality) of these subsets is ultimately dictated by the appropriate integration of extracellular cues such as cytokines with cell intrinsic transcription factors, thereby promoting the necessary gene profile. Moreover, the observation that T-helper cells could exhibit a flexible nature (i.e having shared gene profiles and effector functions) not only demonstrate the efficiency of our immune system but also how such flexibility could have unintended consequences during adverse events such as autoimmunity. An important mediator of such flexibility is cytokines. However, the complete network of factors that come together to co-ordinate cytokine mediated plasticity remain unknown. Thus, the work in this dissertation hope to delineate the factors that collaborate to regulate cytokine induced T-helper cell flexibility. As such, we see that in the presence of IL-2, the Ikaros Zinc Finger (IkZF) transcription factor Eos is upregulated in TH1 cells, with this factor playing a significant role in promoting regulatory and effector functions of TH1 cells. Moreover, we show that Eos forms a novel protein complex with STAT5 and promotes STAT5 activity in TH1 cells. However, depleting IL-2 from the micro-environment leads to the upregulation of two other members within the IkZF family, Ikaros and Aiolos. Aiolos in turn collaborate with STAT3, induces Bcl-6 expression within these cells, thus promoting these cells to exhibit characteristic features of TFH cells. The work in this dissertation hopes to advance our understanding of the regulatory mechanisms involved in cytokine mediated T-cell flexibility thereby hoping to open new avenues for the development of novel therapeutic strategies in the event of autoimmunity. / Ph. D. / T-helper (TH) cells are an important component of the immune system, as these cells aid in the fight against pathogens by secreting factors that either accentuate the inflammatory response during infection or attenuate immune responses post infection. Such effects are made possible because T-helper cells can differentiate into a variety of subsets, with each subset being an important mediator in maintaining immune homeostasis. For example, the T-helper cell subset called TH1 plays a vital role in the fight against intracellular pathogens such as viruses and certain parasites, while T-follicular helper (TFH) cells aid in the production of antibodies specific to the invading pathogen. The development of such subsets occur when cell extrinsic signals, called cytokines, lead to the activation or induction of cell intrinsic proteins called transcription factors. Interestingly, research over the years have shown that T-helper cells are highly adaptable in nature, with one subset having the ability to attain certain characteristic features of other subsets. This malleable nature of T-helper cells relies on several factors, with cytokines within the micro-environment being an important one. Although this form of flexibility is efficient and beneficial at times, it can also be detrimental, as such flexibility is known to promote certain autoimmune diseases such as multiple sclerosis, rheumatoid arthritis and type 1 diabetes. Such detrimental effects are thought to be due to cytokines within the environment. Therefore understanding how cytokines influence the flexible nature of T-helper cells is important; as controlling such flexibility (either by regulating cytokines or the transcription factors activated as a consequence) could prevent the propagation of undesired T-helper cell functions. As such, the work in this dissertation hopes to uncover how one such cytokine, termed Interleukin-2 (IL-2) mediates the flexibility between TH1 and TFH cells. The work highlighted in this dissertation broadens our understanding of how cytokines influence T-helper cell development and flexibility, and consequently allows the design of novel therapeutic strategies to combat autoimmune diseases.
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