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Regulation of Early T-cell Development and Commitment by HEBBraunstein, Marsela 29 August 2011 (has links)
Early T-cell development is regulated by a complex interplay between transcription factors and developmental cues which ensure that functional T-cells are produced within the thymus. Early thymocytes integrate these signals in a step-wise fashion that progressively restricts their lineage potential as they transition through the early stages of T-cell development. Gene knockout studies have shown that the E-protein transcription factor HEB is required for normal thymocyte development. Furthermore, many additional key regulators such as Notch1 have been identified, but the connections among them and their specific roles in early T-cell development have not been well established. In this thesis, I set out to determine the specific roles of HEB at the beta-selection checkpoint and to establish connections between HEB and the key regulators within the gene regulatory network that orchestrates early T-cell development. To facilitate these studies, I generated a series of new mouse models including HEBAlt transgenic mice that express a short form of HEB called HEBAlt, which enabled me to answer specific questions and examine rare populations. First, my studies of HEB-/- mice allowed me to identify an early block in T-cell development, which was alleviated upon the addition of an HEBAlt transgene. Furthermore, I identified pTa and CD3e signalling as specific targets of HEBAlt during -selection. Second, my studies on HEB-/- mice revealed that they have a defect in T-cell commitment, with compromised Notch1 function and a tendency to become DN1-like cells. Moreover, the DN1-like cells could be induced to differentiate into thymic NK cells, revealing a role for HEB in the T/NK cell lineage decision. This study has revealed a new set of interactions among HEB, Notch1, and GATA3 that regulate the T-cell fate choice in developing thymocytes. Unexpectedly, my studies have also provided evidence for a role of HEBAlt in lymphomagenesis, highlighting the strict regulation of E-protein function that is necessary to ensure normal T-cell development.
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Involvement of CD45 in early thymocyte developmentLai, Jacqueline Cheuk-Yan 05 1900 (has links)
CD45 is a protein tyrosine phosphatase that is expressed on all nucleated hematopoietic cells. The major substrates of CD45 in thymocytes and T cells are the Src family kinases Lck and Fyn. The role of CD45 in thymocyte development and T cell activation via its regulation of Src family kinases in T cell receptor signaling has been studied extensively. However, the role of CD45 in processes that affect thymocyte development prior to the expression of the T cell receptor has not been explored.
The overall hypothesis of this study was that CD45 is a regulator of spreading, migration, proliferation, and differentiation of early thymocytes during development in the thymus and the absence of CD45 would alter the outcome of thymocyte development.
The first aim was to determine how CD45 regulates CD44-mediated signaling leading to cell spreading. The interaction between CD44 and Lck was first examined. CD44 associated with Lck in a zinc-dependent and a zinc-independent manner. Mutation analysis localized the zinc-dependent interaction to the membrane proximal region of CD44, but did not involve individual cysteine residues on CD44. CD44 and Lck co-localized in microclusters upon CD44-mediated cell spreading. CD45 co-localized with Lck and CD44 in microclusters and with F-actin in ring structures. The recruitment of CD45 to microclusters may be a mechanism of how CD45 negatively regulates CD44-mediated spreading.
The second specific aim was to determine the role of CD45 in migration, proliferation, and progression and differentiation of early thymocytes. CD45 negatively regulated CXCL12-mediated migration, and positively regulated the proliferation and progression of CD117- DN1 thymocytes. Absence of CD45 led to an altered composition of thymic subsets. The CD45-/- thymus contained decreased numbers of ETPs and an aberrant CD117- DN1 population that lacked CD24, TCRbeta, and CCR7 expression. There were also increased thymic NK and gamma/delta T cells, but decreased NKT cells. In addition, a novel intermediate between DN1 and DN2 that required Notch for progression was identified.
Overall, this study identified new roles for CD45 in early thymocytes and provided a better picture of how the development of T cells, a central component of the immune system, is regulated.
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Cell production, expansion and the role of auxin in the response of the root of Arabidopsis thaliana exposed to water deficit /Van der Weele, Cornelia Maria, January 2001 (has links)
Thesis (Ph. D.)--University of Missouri-Columbia, 2001. / Typescript. Vita. Includes bibliographical references. Also available on the Internet.
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Cell production, expansion and the role of auxin in the response of the root of Arabidopsis thaliana exposed to water deficitVan der Weele, Cornelia Maria, January 2001 (has links)
Thesis (Ph. D.)--University of Missouri-Columbia, 2001. / Typescript. Vita. Includes bibliographical references. Also available on the Internet.
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Involvement of CD45 in early thymocyte developmentLai, Jacqueline Cheuk-Yan 05 1900 (has links)
CD45 is a protein tyrosine phosphatase that is expressed on all nucleated hematopoietic cells. The major substrates of CD45 in thymocytes and T cells are the Src family kinases Lck and Fyn. The role of CD45 in thymocyte development and T cell activation via its regulation of Src family kinases in T cell receptor signaling has been studied extensively. However, the role of CD45 in processes that affect thymocyte development prior to the expression of the T cell receptor has not been explored.
The overall hypothesis of this study was that CD45 is a regulator of spreading, migration, proliferation, and differentiation of early thymocytes during development in the thymus and the absence of CD45 would alter the outcome of thymocyte development.
The first aim was to determine how CD45 regulates CD44-mediated signaling leading to cell spreading. The interaction between CD44 and Lck was first examined. CD44 associated with Lck in a zinc-dependent and a zinc-independent manner. Mutation analysis localized the zinc-dependent interaction to the membrane proximal region of CD44, but did not involve individual cysteine residues on CD44. CD44 and Lck co-localized in microclusters upon CD44-mediated cell spreading. CD45 co-localized with Lck and CD44 in microclusters and with F-actin in ring structures. The recruitment of CD45 to microclusters may be a mechanism of how CD45 negatively regulates CD44-mediated spreading.
The second specific aim was to determine the role of CD45 in migration, proliferation, and progression and differentiation of early thymocytes. CD45 negatively regulated CXCL12-mediated migration, and positively regulated the proliferation and progression of CD117- DN1 thymocytes. Absence of CD45 led to an altered composition of thymic subsets. The CD45-/- thymus contained decreased numbers of ETPs and an aberrant CD117- DN1 population that lacked CD24, TCRbeta, and CCR7 expression. There were also increased thymic NK and gamma/delta T cells, but decreased NKT cells. In addition, a novel intermediate between DN1 and DN2 that required Notch for progression was identified.
Overall, this study identified new roles for CD45 in early thymocytes and provided a better picture of how the development of T cells, a central component of the immune system, is regulated.
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The Role of ATM in Promoting Normal T cell Development and Preventing T Cell LeukemogenesisMatei, Irina 24 September 2009 (has links)
The immune system recognizes and eliminates an enormous array of pathogens due to the diverse antigen receptor repertoire of T and B lymphocytes. However, the development of lymphocytes bearing receptors with unique specificities requires the generation of programmed double strand breaks (DSB) coupled with bursts of proliferation, rendering lymphocytes susceptible to mutations and oncogenic transformation. Thus, mechanisms responsible for monitoring global genomic integrity, such as those coordinated by the ATM (ataxia-telangiectasia mutated) kinase, must be activated during lymphocyte development to limit the oncogenic potential of antigen receptor locus recombination. I show that ATM deficiency compromises TCRα recombination and the post-mitotic survival of T-cell receptor αβ (TCRαβ+) CD4+CD8+ (DP) thymocytes, providing a molecular and developmental basis for the immunodeficiency characteristic of ATM loss. Moreover, I show that in early thymocyte progenitors undergoing TCRβ recombination, ATM loss leads to cell cycle defects and developmental arrest, likely facilitating the acquisition of mutations that contribute to leukemogenesis. Using ATM deficiency as a murine model of T cell precursor acute lymphoblastic leukemia (T-ALL), I demonstrate that IL-7 signaling, a critical survival and proliferation signal during early stages of normal thymocyte development, is also required for leukemic maintenance. Moreover, we show for the first time that in normal and leukemic thymocyte precursors, interleukin 7 receptor (IL-7R) expression and function are controlled by Notch signaling, a key determinant of T cell fate. Collectively, these findings provide insight into the mechanisms by which ATM promotes normal lymphocyte development and protects from neoplastic transformation, while establishing the groundwork for assessing the molecular events that lead to the initiation and stepwise progression of T cell leukemogenesis.
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Critical roles for the transcription factor c-Myb in early B cell developmentGreig, K. T. January 2009 (has links)
B cell development is a carefully orchestrated process involving many transcription factors acting in concert with cytokine signals, particularly IL-7. The transcription factor c-Myb has long been implicated in B cell development, however surprisingly little is known about the function of c-Myb in B cell progenitors. I have used several mouse models of c-Myb deficiency to investigate the role of c-Myb in the B cell lineage. Conditional deletion of c-Myb in early B cell progenitors using mb-1Cre (c MybΔmb1/Δmb1) leads to a striking lack of B cells from the pre-pro-B cell stage onwards, demonstrating that c-Myb is absolutely required for B cell development. Mice homozygous for a hypomorphic allele of c-Myb (c MybPlt4/Plt4) also display a severe reduction in B cells; in these mice, defects in lymphoid development can be detected within the multipotent progenitor compartment of bone marrow. c-Myb activates transcription via coactivator proteins, particularly CBP and p300. Mice bearing a point mutation in p300 (p300Plt6/Plt6) that inhibits the interaction of p300 with c Myb display a partial block in B cell development, highlighting the importance of the c Myb-p300 complex for B cell development. Together, these mice demonstrate that c-Myb regulates B cell development by functioning both in multipotent progenitor cells and directly in B cell progenitors. In addition, I show that the B-lymphopenia in c-Myb deficient mice is related to a profound defect in IL-7 signalling. IL-7 normally stimulates the proliferation, survival and differentiation of B cell progenitors, however pro-B cells from c-MybPlt4/Plt4 and c MybΔmb1/Δmb1 mice fail to respond to IL 7. Expression of the IL-7Rα chain is reduced on pro-B cells from c MybPlt4/Plt4 and c-MybΔmb1/Δmb1 mice, suggesting that Il7r may be a c-Myb target gene in B cells. Reporter gene assays show that c-Myb can activate the Il7r promoter in synergy with the transcription factor Pu.1. Overall, this work demonstrates that c-Myb is essential for early B cell development and plays a critical role in linking cytokine signals to the transcription factor networks in B cell progenitors.
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Organization and function of microtubules and their relationship /Liang, Benjamin Ming-Hwa, January 1997 (has links)
Thesis (Ph. D.)--University of Missouri-Columbia, 1997. / Typescript. Vita. Includes bibliographical references (leaves 122-124). Also available on the Internet.
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Organization and function of microtubules and their relationshipLiang, Benjamin Ming-Hwa, January 1997 (has links)
Thesis (Ph. D.)--University of Missouri-Columbia, 1997. / Typescript. Vita. Includes bibliographical references (leaves 122-124). Also available on the Internet.
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Involvement of CD45 in early thymocyte developmentLai, Jacqueline Cheuk-Yan 05 1900 (has links)
CD45 is a protein tyrosine phosphatase that is expressed on all nucleated hematopoietic cells. The major substrates of CD45 in thymocytes and T cells are the Src family kinases Lck and Fyn. The role of CD45 in thymocyte development and T cell activation via its regulation of Src family kinases in T cell receptor signaling has been studied extensively. However, the role of CD45 in processes that affect thymocyte development prior to the expression of the T cell receptor has not been explored.
The overall hypothesis of this study was that CD45 is a regulator of spreading, migration, proliferation, and differentiation of early thymocytes during development in the thymus and the absence of CD45 would alter the outcome of thymocyte development.
The first aim was to determine how CD45 regulates CD44-mediated signaling leading to cell spreading. The interaction between CD44 and Lck was first examined. CD44 associated with Lck in a zinc-dependent and a zinc-independent manner. Mutation analysis localized the zinc-dependent interaction to the membrane proximal region of CD44, but did not involve individual cysteine residues on CD44. CD44 and Lck co-localized in microclusters upon CD44-mediated cell spreading. CD45 co-localized with Lck and CD44 in microclusters and with F-actin in ring structures. The recruitment of CD45 to microclusters may be a mechanism of how CD45 negatively regulates CD44-mediated spreading.
The second specific aim was to determine the role of CD45 in migration, proliferation, and progression and differentiation of early thymocytes. CD45 negatively regulated CXCL12-mediated migration, and positively regulated the proliferation and progression of CD117- DN1 thymocytes. Absence of CD45 led to an altered composition of thymic subsets. The CD45-/- thymus contained decreased numbers of ETPs and an aberrant CD117- DN1 population that lacked CD24, TCRbeta, and CCR7 expression. There were also increased thymic NK and gamma/delta T cells, but decreased NKT cells. In addition, a novel intermediate between DN1 and DN2 that required Notch for progression was identified.
Overall, this study identified new roles for CD45 in early thymocytes and provided a better picture of how the development of T cells, a central component of the immune system, is regulated. / Science, Faculty of / Microbiology and Immunology, Department of / Graduate
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