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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 lymphoid-myeloid lineage bias through Regnase-1/3-mediated control of Nfkbiz / Regnase-1/3によるNfkbiz発現調節を介したリンパ球-骨髄球の系譜決定制御

Yamada, Shinnosuke 25 March 2024 (has links)
京都大学 / 新制・課程博士 / 博士(医科学) / 甲第25205号 / 医科博第161号 / 新制||医科||11(附属図書館) / 京都大学大学院医学研究科医科学専攻 / (主査)教授 生田 宏一, 教授 伊藤 貴浩, 教授 齋藤 潤 / 学位規則第4条第1項該当 / Doctor of Agricultural Science / Kyoto University / DFAM
2

Understanding Cell Fate Decisions in the Embryonic Gonad

Jameson, Samantha Ann January 2011 (has links)
<p>The divergence of distinct cell populations from multipotent progenitors is poorly understood, particularly <italic>in vivo</italic>. The gonad is an ideal place to study this process because it originates as a bipotential primordium where multiple distinct lineages acquire sex-specific fates as the organ differentiates as a testis or an ovary. The early gonad is composed of four lineages: supporting cells, interstitial/stromal cells, germ cells, and endothelial cells. Each lineage in the early gonad consists of bipotential progenitors capable of adopting either a male or female fate, which they do in a coordinated manner to form a functional testis or ovary. The supporting cell lineage is of particular interest because the decision of these cells to adopt the male or female fate dictates the fate of the gonad as a whole. </p><p><p>To gain a more detailed understanding of the process of gonadal differentiation at the level of the individual cell populations, we conducted microarrays on sorted cells of the four lineages from XX and XY mouse gonads at three time points spanning the period when the gonadal cells transition from sexually undifferentiated progenitors to their respective sex-specific fates. Our analysis identified genes specifically depleted and enriched in each lineage as it underwent sex-specific differentiation. We also determined that the sexually undifferentiated germ cell and supporting cell progenitors showed lineage priming. Multipotent progenitors that show lineage priming express markers of the various fates into which they can differentiate and subsequently silence genes associated with the fate not adopted as they differentiate. We found that germ cell progenitors were primed with a bias toward the male fate. In contrast, supporting cell progenitors were primed with a female bias. This yields new insights into the mechanisms by which different cell types in a single organ adopt their respective fates. </p><p><p>We also used a genetic approach to investigate how individual factors contribute to the adoption of the male supporting cell fate. We previously demonstrated that <italic>Fgf9</italic> and <italic>Wnt4</italic> act as mutually antagonistic factors to promote male or female development of the bipotential mammalian gonad. <italic>Fgf9</italic> is necessary to maintain <italic>Sox9</italic> expression, which drives male development. However, whether FGF9 acted directly on <italic>Sox9</italic> or indirectly through repression of <italic>Wnt4</italic>, was unknown. <italic>Wnt4</italic> is a female-primed gene, and is therefore repressed during male development. To determine how <italic>Fgf9</italic> functioned, we generated double <italic>Fgf9/Wnt4</italic> and <italic>Fgfr2/Wnt4</italic> mutants. While single XY <italic>Fgf9</italic> and <italic>Fgfr2</italic> mutants showed partial or complete male-to-female sex reversal, loss of <italic>Wnt4</italic> in an <italic>Fgf9</italic> or <italic>Fgfr2</italic> mutant background rescued normal testis development. We also found that <italic>Wnt4</italic> and another female-associated gene (<italic>Rspo1</italic>) were derepressed in <italic>Fgf9</italic> mutants prior to the down-regulation of <italic>Sox9</italic>. Thus, the primary function of <italic>Fgf9</italic> is the repression of female genes, including <italic>Wnt4</italic>. We also tested the reciprocal possibility: that de-repression of <italic>Fgf9</italic> was responsible for the aspects of male development observed in XX <italic>Wnt4</italic> mutants. However, we show that loss of <italic>Fgf9</italic> in XX <italic>Wnt4<super>-/-</super></italic> gonads does not rescue the partial female-to-male sex reversal. </p><p><p>Based on the <italic>Fgf9/Wnt4</italic> double mutant studies, we propose a two part model of male sex determination in which both the activation of male genes and repression of female genes is required. Also, this work demonstrates that the repression of the female-primed gene <italic>Wnt4</italic> is required for male development, and <italic>Fgf9</italic> is one factor that leads to the repression of female-primed genes.</p> / Dissertation
3

Investigating TGFβ signals in cell fate specification in the early mouse embryo

Senft, Anna Dorothea January 2016 (has links)
TGFβ signalling via Smad transcription factors is essential for axis patterning and subsequent cell fate specification during mammalian embryogenesis. However, the cellular and molecular mechanisms have been difficult to characterise in vivo due to early embryonic lethality of mouse mutants and redundant functional activities. Here I show that combined deletion of closely related Smad2 and Smad3 in mouse embryonic stem cells impairs induction of lineage specific gene expression during differentiation, while extra-embryonic gene expression is up-regulated. Preliminary data suggest that the underlying mechanism of this differentiation defect reflects the inability of Smad2/3<sup>-/-</sup> cells to establish lineage priming. Collectively, these findings identify novel downstream target genes controlled by Smad2/3 and an absolute requirement for Smad2/3 during embryonic differentiation. TGFβ signalling via Smad1 and Smad4 is essential for induction of the transcription factor Blimp1 required for primordial germ cell specification. The direct upstream regulators of Blimp1 are unknown, but T-box factors have recently been suggested to play a role. In a second project, I performed tissue- specific ablation of the T-box transcription factor Eomes as well as components of the TGFβ signalling pathway in either the visceral endoderm or the epiblast to examine tissue-specific functions for Blimp1 induction. I show that Eomes and Smad2 functions in the visceral endoderm as well as Eomes function in the epiblast are dispensable for Blimp1 induction, but rather are required to restrict Blimp1 induction to posterior epiblast cells. In contrast, epiblast-specific Smad4 or Smad1 mutants fail to robustly induce Blimp1 in the epiblast. My preliminary analysis suggests that competence to induce primordial germ cell fate is dependent on the interplay of Smad2/Eomes functions in the visceral endoderm and Smad1/4 functions in the epiblast. Collectively, this thesis provides insight into the transition from pluripotency to cell fate specification in the mammalian embryo that is impossible to obtain from human embryos in vivo.

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