Global ETD Search

1	Incorporation of bio-inspired microparticles within embryonnic stem cell aggregates for directed differentiation Sullivan, Denise D. 27 May 2016 (has links) Embryonic stem cells (ESCs) are a unique cell population that can differentiate into all three embryonic germ layers (endoderm, mesoderm, and ectoderm), rendering them an invaluable cell source for studying the molecular mechanisms of embryogenesis. Signaling molecules that direct tissue patterning during embryonic development are secreted by ESC aggregates, known as embryoid bodies (EBs). As many of these signaling proteins interact with the extracellular matrix (ECM), manipulation of the ESC extracellular environment provides a means to direct differentiation. ECM components, such as glycosaminoglycans (GAGs), play crucial roles in cell signaling and regulation of morphogen gradients during early development through binding and concentration of secreted growth factors. Thus, engineered biomaterials fabricated from highly sulfated GAGs, such as heparin, provide matrices for manipulation and efficient capture of ESC morphogens via reversible electrostatic and affinity interactions. Ultimately, biomaterials designed to efficiently capture and retain morphogenic factors offer an attractive platform to enhance the differentiation of ESCs toward defined cell types. The overall objective of this work was to examine the ability of microparticles synthesized from both synthetic and naturally-derived materials to enhance the local presentation of morphogens to direct ESC differentiation. The overall hypothesis was that microparticles that mimic the ECM can modulate ESC differentiation through sequestration of endogenous morphogens present within the EB microenvironment. Embryonic stem cells Microparticles Embryoid bodies Heparin Stem cell differentiation
2	Vascular Endothelial Growth Factor Functionalized Agarose Can Efficiently Guide Pluripotent Stem Cell Aggregates Toward Blood Progenitor Cells Rahman, Muhammad Nafeesur 27 July 2010 (has links) Embryonic stem cells (ESCs) are derived from the inner cell mass (ICM) of the embryo that have great potential for regenerative therapies because of their ability to self-renew and differentiate into almost all cell types. However, this developmental potential is influenced by the local cellular microenvironment, including cell surface bound ligands. In this study, we synthesized an artificial stem cell niche wherein vascular endothelial growth factor A (VEGFA) was functionally immobilized in an agarose hydrogel. Immobilized VEGFA treatments were able to upregulate mesodermal markers, brachyury and VEGF receptor 2, by day 4 and were CD34+CD41+ by day seven. Subsequently, VEGFA immobilized treatments were able to generate colony forming cells by day fourteen. This work demonstrates our ability to use functionalized hydrogels to guide ESCs toward blood progenitor cells and serves as a useful tool to replicate aspects of the embryonic microenvironment. Agarose Hydrogel Embryoid Bodies VEGFA Blood Progenitor Cells 3D Differentiation Serum-Free 0541 0542
3	Vascular Endothelial Growth Factor Functionalized Agarose Can Efficiently Guide Pluripotent Stem Cell Aggregates Toward Blood Progenitor Cells Rahman, Muhammad Nafeesur 27 July 2010 (has links) Embryonic stem cells (ESCs) are derived from the inner cell mass (ICM) of the embryo that have great potential for regenerative therapies because of their ability to self-renew and differentiate into almost all cell types. However, this developmental potential is influenced by the local cellular microenvironment, including cell surface bound ligands. In this study, we synthesized an artificial stem cell niche wherein vascular endothelial growth factor A (VEGFA) was functionally immobilized in an agarose hydrogel. Immobilized VEGFA treatments were able to upregulate mesodermal markers, brachyury and VEGF receptor 2, by day 4 and were CD34+CD41+ by day seven. Subsequently, VEGFA immobilized treatments were able to generate colony forming cells by day fourteen. This work demonstrates our ability to use functionalized hydrogels to guide ESCs toward blood progenitor cells and serves as a useful tool to replicate aspects of the embryonic microenvironment. Agarose Hydrogel Embryoid Bodies VEGFA Blood Progenitor Cells 3D Differentiation Serum-Free 0541 0542
4	Impedance measurement system for embryonic stem cell and embryoid body cultures Montgomery, Sarah Lynn 19 May 2008 (has links) The objective of the proposed research is to design an experimental setup to assess the ability of impedance measurements to characterize mouse embryonic stem cell (ESC) and embryoid body (EB) growth and differentiation. Existing quality assurance measurements used to stage the growth and differentiation of embryoid bodies are labor intensive and most often destructive to the cells, thus present methods are typically valid for a single time point. Bioimpedance measurements are non-invasive and non-destructive, presenting an alternative approach to this challenge. These measurements can be done continuously for real-time measurements on the changes in embryoid body growth and differentiation. A system capable of making bioimpedance measurements of ESC and EB suspensions was designed along with a biocompatible test device to hold the cells and Ag-AgCl electrodes. The system uses a lock-in amplifier to record the magnitude and phase changes of the ESC and EB suspensions when a 1 Vpp signal sweeping frequencies from 100 Hz to 100 kHz is applied. The system performance was validated with a test case of 1 mL of 0.1 M KCl. Then experiments with cell culture media, ESCs, and EBs were performed, with varying concentrations of cells and EBs. Experimental results for single ESC suspensions showed promise in detecting a difference in cell concentration between 2 million and 4 million cells in 0.5 mL of media. Results for four day old EBs were ambiguous, and we conclude that a different experimental set up is required due to EB settling during experimentation. Cell suspension Bioimpedance Embryoid bodies Stem cell Impedance Impedance, Bioelectric Embryonic stem cells
5	Understanding Dishevelled-Mediated Wnt Signaling in Regulating Early Development and Stem Cell Differentiation Ngo, Justine Marie 01 June 2020 (has links) No description available. Developmental Biology Genetics Neurosciences Wnt Dishevelled stem cells gastrulation embryoid bodies neural progenitor cells
6	Acellular matrices derived from differentiating embryonic stem cells Nair, Rekha 10 November 2009 (has links) Embryonic stem cells (ESCs) can differentiate into all somatic cells, and as such, are a promising cell source for therapeutic applications. In vitro, ESCs spontaneously differentiate via the aggregation of cells into embryoid bodies (EBs), which recapitulate aspects of early embryogenesis and harbor a unique reservoir of cues critical for tissue formation and morphogenesis. Embryonic healing responses employ similar intrinsic machinery used for tissue development, and these morphogenic cues may be captured within the EB microenvironment. Recent studies have shown that when injected into injury or defect models in vivo, ESCs synthesize and secrete extracellular factors that ultimately contribute to repair, suggesting that these molecules may be as important for regenerative therapies as functional differentiation of the cells. The overall objective of this project was to develop novel acellular matrices derived from differentiating ESCs undergoing morphogenesis. The central hypothesis was that embryonic matrices contain complex mixtures of extracellular factors that, when isolated, retain bioactivity and enhance wound healing in an adult environment. The overall objective was accomplished by: (1) investigating the production of extracellular matrix (ECM) by differentiating ESCs as a function of differentiation time; (2) assessing the ability of solvents to efficiently decellularize EBs; and (3) evaluating the healing response elicited by acellular matrices derived from EBs in a murine dermal wound healing model. Endogenous ECM synthesis by EBs varied with time and was associated with specific differentiation events. Novel techniques were developed to effectively remove cell components from EBs in order to extract complex, bioactive acellular matrices. EB-derived acellular matrices significantly enhanced the healing of excisional dermal wounds in mice, indicating the potency of extracellular factors synthesized by ESCs. All together, these studies demonstrate that acellular matrices derived from ESCs retain morphogenic factors capable of influencing tissue repair. In addition, this work lays the foundation for future studies to further examine the functional role of endogenous matrix molecules on ESC differentiation and to evaluate the utility of a stem cell-derived matrix for a variety of regenerative medicine applications. Regenerative medicine Extracellular matrix Embryoid bodies Embryonic stem cells Dermal wound healing Tissue engineering Wound healing Regeneration (Biology)
7	Roles of the Shb and Cbl Proteins in Signal Transduction and Blood Vessel Formation Lu, Lingge January 2003 (has links) <p>Formation of blood vessels occurs through two processes: vasculogenesis and angiogenesis, which are regulated by various growth factors such as vascular endothelial growth factor, fibroblast growth factor and platelet-derived growth factor. The present study was carried out in order to investigate the roles of the Shb and Cbl proteins in growth factor-mediated signal transduction and blood vessel formation. Shb was found to be involved in NGF-stimulated Rap1 signaling in PC12 cells by forming a complex with CrkII and a 130-135 kDa protein. The Rap1 signaling pathway contributed to NGF-dependent neurite outgrowth. In immortomouse brain endothelial (IBE) cells, Shb increased cell spreading, migration and cytoskeletal rearrangements. Such effects may partly be due to altered Rap1 activation in Shb overexpressing IBE cells. Shb was required for tubular morphogenesis in collagen gels in the presence of FGF-2. In embryoid bodies (EBs) derived from murine embryonic stem cells, Shb up-regulated both VEGFR2 and Tal1 expression at early stages of EB development and thus promoted blood vessel formation both in the absence and in the presence of growth factors. In IBE cells, Cbl positively regulated FGF-2 signaling and increased cell proliferation. Mutation of RING finger alone did not affect blood vessel formation in EBs. However, EBs overexpressing the oncogenic form Cbl 70Z, which had a deletion of the linker region and the first cysteine of the RING finger, exhibited intense CD31 positive sheet-like staining and blood vessel. The results suggested that Cbl had dual roles in endothelial cells: it promoted FGF-2-induced proliferation whereas down-regulated proliferation of endothelial progenitor cells.</p><p>The present work suggests that Shb and Cbl play a crucial role in cell differentiation and blood vessel formation.</p> Cell biology Shb Cbl FGF-2 NGF PDGF VEGF VEGFR-2 differentiation blood vessel formation PC12 cells endothelial cells embryoid bodies Rap1 CrkII Cellbiologi Cell biology Cellbiologi
8	Roles of the Shb and Cbl Proteins in Signal Transduction and Blood Vessel Formation Lu, Lingge January 2003 (has links) Formation of blood vessels occurs through two processes: vasculogenesis and angiogenesis, which are regulated by various growth factors such as vascular endothelial growth factor, fibroblast growth factor and platelet-derived growth factor. The present study was carried out in order to investigate the roles of the Shb and Cbl proteins in growth factor-mediated signal transduction and blood vessel formation. Shb was found to be involved in NGF-stimulated Rap1 signaling in PC12 cells by forming a complex with CrkII and a 130-135 kDa protein. The Rap1 signaling pathway contributed to NGF-dependent neurite outgrowth. In immortomouse brain endothelial (IBE) cells, Shb increased cell spreading, migration and cytoskeletal rearrangements. Such effects may partly be due to altered Rap1 activation in Shb overexpressing IBE cells. Shb was required for tubular morphogenesis in collagen gels in the presence of FGF-2. In embryoid bodies (EBs) derived from murine embryonic stem cells, Shb up-regulated both VEGFR2 and Tal1 expression at early stages of EB development and thus promoted blood vessel formation both in the absence and in the presence of growth factors. In IBE cells, Cbl positively regulated FGF-2 signaling and increased cell proliferation. Mutation of RING finger alone did not affect blood vessel formation in EBs. However, EBs overexpressing the oncogenic form Cbl 70Z, which had a deletion of the linker region and the first cysteine of the RING finger, exhibited intense CD31 positive sheet-like staining and blood vessel. The results suggested that Cbl had dual roles in endothelial cells: it promoted FGF-2-induced proliferation whereas down-regulated proliferation of endothelial progenitor cells. The present work suggests that Shb and Cbl play a crucial role in cell differentiation and blood vessel formation. Cell biology Shb Cbl FGF-2 NGF PDGF VEGF VEGFR-2 differentiation blood vessel formation PC12 cells endothelial cells embryoid bodies Rap1 CrkII Cellbiologi Cell biology Cellbiologi
9	Caracterização da expressão de Coup-TFII durante o início da diferenciação de células-tronco embrionárias / Characterization of Coup-TFII expression during the early differentiation of embryonic stem cells Rosa, Viviane de Souza, 1988- 27 August 2018 (has links) Orientador: Henrique Marques Barbosa de Souza / Dissertação (mestrado) - Universidade Estadual de Campinas, Instituto de Biologia / Made available in DSpace on 2018-08-27T10:31:42Z (GMT). No. of bitstreams: 1 Rosa_VivianedeSouza_M.pdf: 2727894 bytes, checksum: d0d5ab88ca9670f3109f39586f01a78c (MD5) Previous issue date: 2015 / Resumo: Células-tronco embrionárias (CTE) são células indiferenciadas que possuem a capacidade de (1) se proliferarem indefinidamente (auto-renovação) e, quando induzidas, (2) darem origem a qualquer tipo celular presente no embrião (pluripotência). Uma das abordagens mais comumente utilizadas para o estudo de diferenciação de CTE é através da formação de agregados multicelulares esféricos denominados corpos embrióides (CE). CE passam por um processo de morfogênese semelhante ao observado em embriões, originando derivados dos três folhetos germinativos. Durante o desenvolvimento embrionário, a formação e o posicionamento dos três folhetos ocorre por um processo altamente coordenado que culmina na formação de um embrião polarizado no eixo anteroposterior. Entretanto, um dos grandes desafios de pesquisas que envolvem o uso da diferenciação de CTE em CE é encontrar indícios de que esses processos são recapitulados in vitro e se entender como que células derivadas dos folhetos germinativos, que no embrião ocorrem de forma altamente organizada, são originadas em estruturas celulares sem nenhuma organização global evidente, como visto em CE. Coup-TFII (Chicken ovalbumin upstream promoter-transcription factor II) é um fator de transcrição o qual possui um papel fundamental na regulação do desenvolvimento embrionário e na aquisição de destinos celulares específicos durante a diferenciação de CTE. Utilizando CE como um modelo de estudo, caracterizamos a expressão de Coup-TFII e seu possível envolvimento durante a determinação de destinos celulares. Nossos resultados identificaram uma expressão hemisférica de Coup-TFII em CE em etapas inicias do processo de diferenciação. Esta observação nos levou a caracterizar a distribuição espacial de marcadores moleculares tecido-específicos nos CE em relação à expressão hemisférica de Coup-TFII. Interessantemente, praticamente todas as células identificadas como precursores mesodérmicos e precursores neuroectodérmicos, através da expressão de Brachyury-T e Nestin, respectivamente, estão contidas nas população de células Coup-TFII-positivas. Estes resultados sugerem a existência de um mecanismo de organização global intrínseco nas CTE, onde a expressão de Coup-TFII parece segregar os CE em dois hemisférios e, provavelmente de forma antagônica com Oct4, determinaria diferentes destinos celulares ainda em fases iniciais da diferenciação / Abstract: Embryonic stem cells (ESC) are undifferentiated cells that have the ability to (1) proliferate indefinitely (self-renewal) and when induced, (2) give rise to any cell type present in the embryo (pluripotency). One of the most commonly used approaches for the study of ESC differentiation is through the formation of spherical multicellular aggregates called embryoid bodies (EB). EB undergo a process similar to that observed in morphogenesis embryos, giving derivatives of three germ layers. During embryonic development, formation and placement of the three germ layers is a highly coordinated process by which culminates in the formation of a polarized embryo in the antero-posterior axis. However, one of the great challenges of research involving the use of ESC differentiation in EB is to find evidence that these processes are recapitulated in vitro and in understanding how to cells derived from the germ layers that occurs in the embryo highly organized manner originate on cellular structures with no apparent global organization, as seen in the EB. COUP-TFII (chicken ovalbumin promoter-upstream transcription factor II) is a transcription factor which plays a key role in the regulation of embryonic development and determination of specific cell fates during differentiation ESC. Using EB as a model system, we characterized the expression of Coup-TFII and its possible involvement in the determination of cell fates. Our results identified a hemispheric expression of Coup-TFII in EB at the onset of differentiation. This observation led us to characterize the spatial distribution of tissue-specific molecular markers in EB in relation the hemispheric expression of Coup-TFII. Interestingly, practically all cells identified as mesodermal and neuroectodermal precursors by the expression of Brachyury-T and Nestin, respectively, are contained in the COUP-TFII-positive cell population. These results suggest the existence of a mechanism of global organization intrinsic to ESC, where the expression of Coup-TFII segregates the EB into two hemispheres and probably antagonistically with Oct4, determine different cell fates still in early stages of differentiation / Mestrado / Biologia Tecidual / Mestra em Biologia Celular e Estrutural Fator II de transcrição COUP Células-tronco embrionárias Diferenciação celular Corpos embrióides Camadas germinativas COUP transcription factor II Embryonic stem cells Cell differentiation Embryoid bodies Germ layers
10	Investigarion of Activated Phosphaidylinositol 3’ Kinase Signaling in Stem Cell Self-renewal and Tumorigenesis Ling, Ling 31 August 2012 (has links) The phosphatidylinositol 3' kinase (PI3K) pathway is involved in many cellular processes including cell proliferation, survival, and glucose transport, and is implicated in various disease states such as cancer and diabetes. Though there have been numerous studies dissecting the role of PI3K signaling in different cell types and disease models, the mechanism by which PI3K signaling regulates embryonic stem (ES) cell fate remains unclear. It is believed that in addition to proliferation and tumorigenicity, PI3K activity might also be important for self-renewal of ES cells. Paling et al. (2004) reported that the inhibition of PI3K led to a reduction in the ability of leukemia inhibitory factor (LIF) to maintain self-renewal causing cells to differentiate. Studies in our lab have revealed that ES cells completely lacking GSK-3 remain undifferentiated compared to wildtype ES cells. GSK-3 is negatively regulated by PI3K suggesting that PI3K may play a vital role in maintaining pluripotency in ES cells through GSK-3. By using a modified Flp recombinase system, we expressed activated alleles of PDK-1 and PKB to create stable, isogenic ES cell lines to further study the role of the PI3K signaling pathway in stem cell fate determination. In vitro characterization of the transgenic cell lines revealed a strong tendency towards maintenance of pluripotency, and this phenotype was found to be independent of canonical Wnt signal transduction. To assess growth and differentiation capacity in vivo, the ES cell lines were grown as subcutaneous teratomas. The constitutively active PDK-1 and PKB ES cell lines were able to form all three germ layers when grown in this manner – in contrast to ES cells engineered to lack GSK-3. The resulting PI3K pathway activated cells exhibited a higher growth rate which resulted in large teratomas. In summary, PI3K signaling is sufficient to maintain self-renewal and survival of stem cells. Since this pathway is frequently mutationally activated in cancers, its effect on suppressing differentiation may contribute to its oncogenicity. PI3K pathway PDK1 myr-PDK1 PKB PKB-DD GSK-3 p70S6K β-catenin Axin-2 Wnt pathway embyronic stem cells pluripotency self-renewal Oct-4 cell fate differentiation embryoid bodies teratoma formation tumorigenesis Akti-1/2 mTOR rapamycin endothelial cells vascularization proliferation apoptosis Flp-In system isogenic cell lines signal transduction myristoylation phosphomimetic 0307 0379

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