Global ETD Search

241	EFA6A/ARF6 signaling and functions in glioblastoma carcinogenesis Li, Ming, 李明 January 2006 (has links) published_or_final_version / abstract / Chemistry / Doctoral / Doctor of Philosophy ADP-ribosylation. Cellular signal transduction. Glioblastoma multiforme. Carcinogenesis.
242	Calcium signaling pathways and cell proliferation in human cardiac fibroblast Chen, Jingbo, 陳靜波 January 2008 (has links) published_or_final_version / Medicine / Master / Master of Philosophy Calcium channels. Cellular signal transduction. Cell proliferation. Fibroblasts. Heart cells.
243	Immune response and signaling mechanisms of Helicobacter pylori induced gastritis Wong, Lik-wai, Benny., 黃力偉. January 2009 (has links) published_or_final_version / Medicine / Doctoral / Doctor of Philosophy Helicobacter. Cellular signal transduction. Gastritis - Immunological aspects. Gastritis - Molecular aspects.
244	Novel mechanisms for SOCS-3 regulation in grass carp: synergistic actions of growth hormone and glucagon at thehepatic level Xiao, Jia, 肖佳 January 2009 (has links) published_or_final_version / Biological Sciences / Master / Master of Philosophy Somatotropin. Glucagon. Cytokines. Cellular signal transduction. Carp - Molecular aspects.
245	Innate immune responses and signaling pathways in influenza A (H5N1) infected human primary macrophages Hui, Pui-yan., 許珮茵. January 2008 (has links) published_or_final_version / Microbiology / Doctoral / Doctor of Philosophy Macrophages. Chemokines. Cellular signal transduction. Immunosuppression. Influenza A virus.
246	Differential regulation of FOXM1 isoforms by RaF/MEK/ERK signaling Lam, King-yin, Andy., 林敬賢. January 2010 (has links) published_or_final_version / Biochemistry / Master / Master of Philosophy Transcription factors. Mitogen-activated protein kinases. Cellular signal transduction.
247	PKB/PAK4 and stem cell related signaling pathways in gestational trophoblastic disease Zhang, Huijuan, 张慧娟 January 2010 (has links) published_or_final_version / Pathology / Doctoral / Doctor of Philosophy Protein kinases. Stem cells. Cellular signal transduction. Trophoblastic tumors.
248	SELECTIVE REGULATION OF CARDIOMYOCYTE SIGNALING BY RGL2 Allen, Leah M. 01 January 2008 (has links) A key cardiovascular signaling molecule involved in both physiologic and pathologic regulation of cardiomyocytes is the small molecular weight G-protein, Ras. Differential effects of Ras are mediated by multiple effector molecules, including the RalGEFs which activate Ral. Studies performed in cardiomyocytes have indicated a role for Ral in cardiac hypertrophic signaling and the RalGEF family member, Rgl2, was shown to specifically interact with Ras in the heart. Therefore, I hypothesized that Rgl2 was an important Ras effector that would regulate cardiomyocyte signaling. To elucidate the potential importance of Rgl2 in regulating cardiomyocyte signaling, a gain-of-function approach was utilized in which NRVMs were infected with an adenovirus to increase Rgl2 expression. Using this approach, I found that Rgl2 increased Ral-GTP levels, Ras-GTP levels, and PI3-kinase-Akt signaling, but decreased ERK phosphorylation. Overall, my results suggest a model in which Rgl2 disrupts Ras-Raf and Ras-RasGAP interaction to decrease ERK phosphorylation and increase Ras-GTP, respectively. Furthermore, Rgl2-induced Ral activation promotes the enhanced PI3- kinase-Akt signaling. The physiologic consequence of Rgl2 signaling is difficult to predict, but the increase in PI3-kinase-Akt signaling would be expected to promote cardiomyocyte survival and enhance cardiac function, both of which are characteristic of physiologic hypertrophy. Rgl2 Ras Signal transduction Cardiomyocyte Insulin Pharmacy and Pharmaceutical Sciences
249	Genetic analyses of terminal differentiation of hypertrophic chondrocytes Yang, Liu, 楊柳 January 2009 (has links) published_or_final_version / Biochemistry / Doctoral / Doctor of Philosophy Cytogenetics Bone cells Cellular signal transduction Cell differentiation Cartilage cells
250	Genetic interaction between Patched1 and Sox10 in enteric nervous system development Tam, Chun-yat, 譚俊逸 January 2014 (has links) The enteric nervous system (ENS) is derived from neural crest cells (NCCs). Once these NCCs reach the foregut, they are recognized as enteric NCCs(ENCCs) which subsequently colonize the gastrointestinal track. The proliferation, migration and neuronal versusglial differentiation of ENCCs are tightly controlled by multiple signaling pathways and transcription factors. Impaired ENS development may result in various human congenital disorders such as Hirschsprung disease(HSCR). Hedgehog (Hh) signaling is a key element in ENS development. Patched-1 (Ptch1) is a negatively regulated receptor for Hh. Binding to Hh or deletion of Ptch1releases its inhibitory function and activates the Hh signaling cascade. Our group has previously revealedPTCH1as a susceptibility gene for HSCR. In particular, NCC-specific deletionofPtch1in mice led to premature glial differentiation and depletion of proliferative ENCC pool, but the molecular mechanisms are still not very clear. Sox10, a member of SRY-related HMG-box family transcription factor, is implicated in these two processes of ENS development. It prompted us to hypothesis that Ptch1 may interact with Sox10 to control ENCC proliferation and glial lineage differentiation. In this study, I generated compound mouse mutants to i) investigate the potential functional interaction between Ptch1 and Sox10 in ENCC differentiation and proliferation, and ii) examine the link between the perturbed NCC differentiation and aberrant proliferation of ENS progenitors, to determine how interruption of these processes may lead to intestinal hypoganglionosis of Ptch1mutants. I found that persistent Hh activation through deletionofPtch1causes a differentiation bias toward glial lineage. Ptch1mutants consistently contained more Sox10expressing glial committed ENCCs and exhibited premature gliogenesis. To test whether elevated Sox10expressing cells contribute in the ENS phenotypes of Ptch1 mutants, 〖Sox10〗^(NGFP/+); Ptch1 compound mutants were generated, where one copy of Sox10 was deleted. Immunohistochemical analysis revealed that 〖Sox10〗^(NGFP/+) mutants exhibitpremature neurogenesis as reported previously, while the proliferation and glial differentiation of ENCCs are not affected.On the other hand, in the compound mutants, heterozygous deletion of Sox10 markedly rescued premature gliogenesis caused by deletion of Ptch1. These data suggest that Ptch1 regulates gliogenesis of ENCCs through maintaining Sox10 expression. To delineate how premature glial differentiation of ENCCs leads to hypoganglionosis, I further investigated whether the differentiation defect perturbs the proliferation capacities of ENCCs. Correction of glial differentiation defect in Ptch1 mutant by heterogeneous deletion of Sox10 could significantly restore the pool size of the proliferative ENCCs of the compound mutant. This observation implies that proliferation defects in Ptch1 mutant represents a secondary consequence of premature gliogenesis, highlighting the close link between these two developmental processes. In summary, the current study provides evidence that Sox10 works coordinately with Ptch1 to mediate ENS development. Loss of Ptch1 favors glial differentiation and formation ofSox10 expressing glial progenitors, leading to intestinal hypoganglionosis as seen in Hirschsprung’s disease. / published_or_final_version / Surgery / Master / Master of Philosophy Cellular signal transduction Transcription factors Autonomic nervous system Neurogenetics

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