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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
1

Regulation of Early T-cell Development and Commitment by HEB

Braunstein, 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.
2

Regulation of Early T-cell Development and Commitment by HEB

Braunstein, 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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