Global ETD Search

21	Mitochondrial Distribution in Mammalian Cells Jiang, Lei 28 December 2009 (has links) No description available. Biology Cellular Biology mitochondrial distribution embryonic stem cell
22	Rat umbilical cord derived stromal cells maintain markers of pluripotency: Oct4, Nanog, Sox2, and alkaline phosphatase in mouse embryonic stem cells in the absence of LIF and 2‐MCE Hong, James S. January 1900 (has links) Master of Science / Department of Anatomy and Physiology / Mark L. Weiss / When mouse embryonic stem cells (ESCs) were grown on mitotically inactivated rat umbilical cord-derived stromal cells (RUCs) in the absence of leukemia inhibitory factor (LIF) and 2-mercaptoethanol (2-MCE), the ESCs showed alkaline phosphatase (AP) staining. ESCs cultured on RUCs maintain expression of the following pluripotency genes, Nanog, Sox2 and Oct4 and grow at a slower rate when compared with ESCs grown on mitotically inactivated mouse embryonic fibroblasts (MEFs). Differences in gene expression for the markers of pluripotency Oct4, Sox2 and Nanog, AP staining and ESC growth rate were also observed after LIF and 2-MCE were removed from the co-cultures. Reverse transcriptase polymerase chain reaction (RT-PCR) suggested differences in Sox2 and Nanog mRNA expression, with both genes being expressed at higher levels in the ESCs cultured on RUCs in the absence of LIF/2-MCE as compared to ESCs cultured on MEFs. Semi-quantitative RT-PCR indicated that Nanog expression was higher when ESCs were grown on RUCs in the absence of LIF and 2-MCE as compared to MEFs in the same treatment conditions. Bisulfite-mediated methylation analysis of the Nanog proximal promoter suggested that the maintenance of Nanog gene expression found in ESCs grown on RUCs after culture for 96 hours in the absence of LIF/2-MCE may be due to prevention of methylation of the CpG dinucleotides in the Nanog proximal promoter as compared to ESCs grown on MEFs. Thus, RUCs may release factors into the medium that maintain the pluripotent state of mouse ESCs in the absence of LIF and 2-MCE. Mouse embryonic stem cell physiology epigenetic regulation of pluripotency cell culture Biology, Cell (0379) Biology, Molecular (0307) Biology, Veterinary Science (0778)
23	Development of a bioreactor imaging system for characterizing embryonic stem cell-derived cardiomyocytes Abilez, Oscar John 21 September 2010 (has links) Cardiovascular disease (CVD) affects more than 70 million Americans and is the number one cause of mortality in the United States. Because the regenerative capacity of adult tissues such as the heart is limited, human embryonic stem cells (hESC) have emerged as a source for potential cardiac therapies. However, despite the use of a variety of biochemical differentiation protocols, current yields of hESC-derived cardiomyocytes (CM) have been low. In the case of hESC-CM, which are inherently electromechanically active, additional forms of inducing a mature cardiac fate have not been fully explored. In order to non-invasively visualize and quantify biochemical, electrical, and mechanical stimulation on hESC-CM differentiation in future studies, a bioreactor imaging system has been developed and is described in this report. / text Cardiovascular disease Heart Human embryonic stem cell hESC Cardiomyocytes Bioreactor Imaging system Regenerative medicine Tissue engineering
24	Início e manutenção da inativação do cromossomo X em células humanas / Establishment and maintenance of X-chromosome inactivation in human cells Fraga, Ana Maria 16 April 2012 (has links) Em fêmeas de mamíferos, um dos cromossomos X é inativado proporcionando compensação de dose entre os produtos gênicos de machos e fêmeas. A inativação do cromossomo X (ICX) ocorre no embrião em desenvolvimento, e se caracteriza pela aquisição de marcas heterocromáticas no cromossomo X inativado (Xi), que são mantidas nas células somáticas ao longo das divisões celulares. O melhor modelo para estudo do início da ICX são as células-tronco embrionárias femininas. Provenientes da massa celular interna de blastocistos, elas representam um embrião em desenvolvimento e possuem os dois X ativos; a diferenciação das células promove a ICX in vitro, o que permite a identificação dos fatores e mecanismos moleculares envolvidos. A derivação de linhagens de célulastronco embrionárias humanas (human embryonic stem cells - hESCs) em 1998 permitiu novas possibilidades de estudo da ICX, pois a maioria dos trabalhos procurou esclarecer o mecanismo da ICX no modelo murino. Tradicionalmente, a manutenção da ICX em humanos tem sido investigada em células somáticas híbridas ou transformadas; porém, sabe-se que estas não representam um contexto celular natural. Assim, o presente trabalho teve como objetivos principais explorar a potencialidade de hESCs no estudo do início da ICX, e ainda investigar a função de três fatores na manutenção da ICX em células humanas imortalizadas: DNMT1 (enzima responsável pela manutenção da metilação do DNA), SMCHD1 (proteína da família de coesinas/condensinas), e XIST (um RNA não-codificador que inicia o processo de heterocromatinização do futuro Xi) foram selecionados para este estudo, uma vez que todos participam da manutenção da ICX em camundongos. Até o momento foram derivadas em nosso laboratório quatro linhagens de hESCs, as primeiras da América Latina. A caracterização das linhagens mostrou que, apesar de se manterem indiferenciadas, as hESCs femininas encontram-se em estágio pós-ICX, pois mesmo indiferenciadas já apresentam um dos X inativado. Nossos dados indicam que, submetidas às atuais condições de cultivo, as hESCs não são bons modelos para o estudo do início da ICX, e é possível que a inativação de um cromossomo X durante o cultivo confira alguma vantagem seletiva às células. A estratégia utilizada no estudo da manutenção da ICX foi o silenciamento dos três genes por interferência de RNA (RNAi). Não foi possível diminuir significativamente a expressão dos genes XIST e SMCHD1. Porém, o silenciamento de DNMT1 foi expressivo, e em resposta foi observada reativação do gene MAOA, localizado no cromossomo X e submetido à inativação. Apesar de nossas análises mostrarem que os efeitos da diminuição de DNMT1 foram restritos ao gene MAOA, estes resultados sugerem a existência de diferentes hierarquias de controle epigenético dos genes submetidos à ICX em células humanas / In female mammals, one of the X chromosomes is inactivated to achieve dosage compensation between males and females. The X chromosome inactivation (XCI) occurs early during embryogenesis and is characterized by the acquisition of heterochromatic features on the inactive X (Xi), which are maintained during all the subsequent cell divisions. Embryonic stem cells are the most suitable cells to study the establishment of XCI. They are obtained from the inner cell mass (ICM) of blastocysts, and can represent a developing female embryo, possessing two active X-chromosomes; when differentiated, these cells recapitulate XCI in vitro, and thus one can identify XCI regulators and factors involved. The derivation of human embryonic stem cells (hESCs) in 1998 offered new possibilities to study XCI, since most of the mechanistic studies of XCI have so far been investigated in the mouse model system. Traditionally, maintenance of XCI in humans has been addressed in somatic cell hybrids or transformed cells; however, they do not represent a natural cellular context. The main goals of the present work were to verify the potential of hESCs as models of XCI, and also to study the function of three important factors in XCI maintenance in immortalized human cells. DNMT1 (DNA-methyltransferase 1), SMCHD1 (a cohesin/condensin protein family member) and the XIST gene (a non-coding RNA which triggers XCI and promotes X heterochromatin formation on the future Xi) were selected, as they are key factors in XCI maintenance in the mouse. Until now four hESCs lines were derived in our lab. Their characterization showed that, in spite of been undifferentiated, the female hESCs have already undergone XCI. Our data suggest that, under the actual culture conditions, hESCs are not good models to study XCI, and it is also possible that X inactivation confers selective advantage to hESCs. Knockdown by RNA interference was used to study the roles of three genes in XCI maintenance. We could not efficiently knockdown XIST or SMCHD1. However, the DNMT1 silencing was substantial, and led to the reactivation of MAOA, an X-linked gene subjected to XCI. Although the effect of DNMT1 silencing was restricted to MAOA, our data suggest that there are different epigenetic hierarchies to control the expression of the genes subjected to XCI in human cells. Células-tronco embrionária humana Epigenetic Epigenética Human embryonic stem cell Inativação do cromossomo X X-chromosome inactivation
25	Hypoxia, PDGF and VEGF in Vascular Development Nilsson, Ingrid January 2006 (has links) <p>The mechanisms behind many important aspects of blood- and lymphatic vessel formation have yet not been elucidated in detail. The primary objectives of this thesis have therefore been to study the effects of hypoxia, platelet-derived growth factor (PDGF) and vascular endothelial growth factors (VEGFs) on vascular development and function. </p><p>In conditions of low oxygen pressure, hypoxia, the survival of the organism is critically dependent on the ability to compensate for the reduced oxygen levels by promoting blood vessel growth and oxygen-independent energy production. Many direct effects of hypoxia in cells are attributed to the induction of a family of hypoxia-inducible transcription factors (HIFs) which control the expression of specific target genes. We found that capillary endothelial cells (ECs) respond to hypoxia with upregulation of genes involved in growth and remodeling of blood vessels. On the other hand, vein ECs responded to hypoxia with increased expression of genes involved in lymphatic vessel growth. Using differentiating embryonic stem (ES) cells, we have shown that hypoxia upregulates expression of VEGF receptor-3 (VEGFR-3) on blood vascular ECs. Furthermore, we have provided evidence for a critical role of VEGFR-3 in hypoxia-induced blood vessel development. </p><p>Activation of PDGF receptor-β (PDGFR-β) on early vascular progenitors in differentiating ES cells or in mice induces blood vessel differentiation, while negatively influencing early hematopoiesis. PDGFR-β expression on vascular progenitors may therefore play a role in guiding differentiation of the vascular lineages. </p><p>We have investigated the usefulness of differentiating ES cells as a model to study early lymphatic development. Administration of VEGF-C and VEGF-A induced formation of lymphatic vessel-like structures that seemed connected to the blood vasculature, supporting the general view that lymphatic ECs are derived from blood vascular ECs.</p><p>In summary, this thesis has provided new insights in the contribution of different growth factors in hematopoietic, blood- and lymphendothelial development. </p> Cell biology hypoxia VEGF VEGFR-3 PDGF endothelial cell embryonic stem cell angiogenesis lymphangiogenesis Cellbiologi
26	A Novel Model System is Applied to Examine the Interplay of Notch and GATA Factors during T Lineage Committment de Pooter, Renee 20 January 2009 (has links) T lymphocytes comprise one arm of the adaptive immune system and are critical for immunity to neoplasia and infection. A full understanding of their development has important implications for the treatment of autoimmunity, immunodeficiency, and leukemias arising from T cell developmental intermediates. The Notch signaling pathway is already known to be absolutely required for T cell commitment and development, but its collaboration with other factors is poorly understood. Unfortunately, deficiency in many of the genes critical to hematopoiesis, including Notch, causes early embryonic lethality by disrupting multiple developmental processes. This complicates the study of such genes by in vivo models or ex vivo hematopoietic progenitors. To circumvent these difficulties, this thesis describes the use of in vitro-differentiated embryonic stem cell-derived T progenitors to examine the roles of two GATA family members during early T cell development. GATA-2, while not required for T cell development, is shown to act downstream of Notch signals to inhibit myelopoiesis. These findings both characterize a novel role for GATA-2, and demonstrate that T progenitor maturation and exclusion of non-T cell fates are distinct and separable events. GATA-3, in contrast to GATA-2, is absolutely required for T lymphopoiesis. However, the current literature does not distinguish between a requirement for GATA-3 in homing to the thymic environment, committing to the T cell fate, or surviving such a commitment event. This thesis demonstrates that GATA-3 is dispensable for commitment itself, but required to permit survival and proliferation after commitment. Taken together, the results presented in this thesis employ a novel model system to characterize the interactions of two important collaborators with Notch signals during T cell development, and further dissect the stages through which early T cell development is enacted. lymphopoiesis T cell development OP9-DL1 embryonic stem cell GATA Notch 0982
27	A Novel Model System is Applied to Examine the Interplay of Notch and GATA Factors during T Lineage Committment de Pooter, Renee 20 January 2009 (has links) T lymphocytes comprise one arm of the adaptive immune system and are critical for immunity to neoplasia and infection. A full understanding of their development has important implications for the treatment of autoimmunity, immunodeficiency, and leukemias arising from T cell developmental intermediates. The Notch signaling pathway is already known to be absolutely required for T cell commitment and development, but its collaboration with other factors is poorly understood. Unfortunately, deficiency in many of the genes critical to hematopoiesis, including Notch, causes early embryonic lethality by disrupting multiple developmental processes. This complicates the study of such genes by in vivo models or ex vivo hematopoietic progenitors. To circumvent these difficulties, this thesis describes the use of in vitro-differentiated embryonic stem cell-derived T progenitors to examine the roles of two GATA family members during early T cell development. GATA-2, while not required for T cell development, is shown to act downstream of Notch signals to inhibit myelopoiesis. These findings both characterize a novel role for GATA-2, and demonstrate that T progenitor maturation and exclusion of non-T cell fates are distinct and separable events. GATA-3, in contrast to GATA-2, is absolutely required for T lymphopoiesis. However, the current literature does not distinguish between a requirement for GATA-3 in homing to the thymic environment, committing to the T cell fate, or surviving such a commitment event. This thesis demonstrates that GATA-3 is dispensable for commitment itself, but required to permit survival and proliferation after commitment. Taken together, the results presented in this thesis employ a novel model system to characterize the interactions of two important collaborators with Notch signals during T cell development, and further dissect the stages through which early T cell development is enacted. lymphopoiesis T cell development OP9-DL1 embryonic stem cell GATA Notch 0982
28	Hypoxia, PDGF and VEGF in Vascular Development Nilsson, Ingrid January 2006 (has links) The mechanisms behind many important aspects of blood- and lymphatic vessel formation have yet not been elucidated in detail. The primary objectives of this thesis have therefore been to study the effects of hypoxia, platelet-derived growth factor (PDGF) and vascular endothelial growth factors (VEGFs) on vascular development and function. In conditions of low oxygen pressure, hypoxia, the survival of the organism is critically dependent on the ability to compensate for the reduced oxygen levels by promoting blood vessel growth and oxygen-independent energy production. Many direct effects of hypoxia in cells are attributed to the induction of a family of hypoxia-inducible transcription factors (HIFs) which control the expression of specific target genes. We found that capillary endothelial cells (ECs) respond to hypoxia with upregulation of genes involved in growth and remodeling of blood vessels. On the other hand, vein ECs responded to hypoxia with increased expression of genes involved in lymphatic vessel growth. Using differentiating embryonic stem (ES) cells, we have shown that hypoxia upregulates expression of VEGF receptor-3 (VEGFR-3) on blood vascular ECs. Furthermore, we have provided evidence for a critical role of VEGFR-3 in hypoxia-induced blood vessel development. Activation of PDGF receptor-β (PDGFR-β) on early vascular progenitors in differentiating ES cells or in mice induces blood vessel differentiation, while negatively influencing early hematopoiesis. PDGFR-β expression on vascular progenitors may therefore play a role in guiding differentiation of the vascular lineages. We have investigated the usefulness of differentiating ES cells as a model to study early lymphatic development. Administration of VEGF-C and VEGF-A induced formation of lymphatic vessel-like structures that seemed connected to the blood vasculature, supporting the general view that lymphatic ECs are derived from blood vascular ECs. In summary, this thesis has provided new insights in the contribution of different growth factors in hematopoietic, blood- and lymphendothelial development. Cell biology hypoxia VEGF VEGFR-3 PDGF endothelial cell embryonic stem cell angiogenesis lymphangiogenesis Cellbiologi
29	Microsphere-mediated control of embryoid body microenvironments Carpenedo, Richard L. 05 April 2010 (has links) Embryonic stem cells (ESCs) hold great promise for treatment of degenerative disorders such as Parkinson's and Alzheimer's disease, diabetes, and cardiovascular disease. The ability of ESCs to differentiate to all somatic cell types suggests that they may serve as a robust cell source for production of differentiated cells for regenerative medicine and other cell-based therapeutics. In order for ESCs to be used effectively in clinical settings, efficient and reproducible differentiation to targeted cell types must be demonstrated. The overall objective of this project was to engineer microenvironmental control over differentiating ESCs through the formation of embryoid bodies (EBs) uniform in size and shape, and through the incorporation of morphogen-containing polymer microspheres within the interior of EBs. The central hypothesis was that morphogen delivery through incorporated polymer microspheres within a uniform population of EBs will induce controlled and uniform differentiation of ESCs. Rotary suspension culture was developed in order to efficiently produce uniform EBs in high yield. Compared to static suspension culture, rotary suspension significantly improved the production of differentiating cells and EBs over the course of 7 days, while simultaneously improving the homogeneity of EB size and shape compared to both hanging drop and static EBs. The diffusive transport properties of EBs formed via rotary suspension were investigated using a fluorescent, cell permeable dye to model the movement of small morphogenic molecules within EBs. Confocal microscopy, cryosections and EB dissociation all demonstrated that the dye was not able to fully penetrate EB, and that the larger EBs at later time points (7 days) retarded dye movement to a greater extent than earlier EBs (days 2 and 4). Polymer microspheres capable of encapsulating morphogenic factors were incorporated into EBs in order to overcome the diffusional limitations of traditional soluble delivery. The size of microspheres, microsphere coating, microsphere to cell ratio, and rotary mixing speed were all observed to influence incorporation within EBs. The use of microsphere-mediated delivery within EBs to direct cell differentiation was examined. Microsphere-mediated delivery of retinoic acid (RA) induced formation of uniquely cystic spheroids with a visceral endoderm layer enveloping a pseudo-stratified columnar epithelium, and with spatial localization of transcriptional profiles similar to the early primitive streak stage of mouse development. Continued differentiation of RA MS EBs in defined media conditions was assessed. Gene expression demonstrated that regular serum enhanced endoderm induction, serum-free media supported ectoderm differentiation, while mesoderm was most prominent in untreated EBs in full serum. In summary, this work has realized a unique approach for stem cell differentiation through modification of the internal microenvironment of ESC spheroids. This novel inside-out method toward engineering EBs demonstrated that the mode of morphogen delivery significantly affected the course of differentiation. These studies provide the basis for ongoing work, which will utilize the choice of microsphere material, coating, and morphogen in order to uniquely study mechanisms of ESC differentiation and achieve unparalleled engineering of the EB microenvironment. Microsphere Retinoic acid Embryoid body Embryonic stem cell Stem cells Tretinoin Degeneration (Pathology) Regenerative medicine
30	The role of Src homology 2 domain containing 5' inositol phosphatase 1 (SHIP) in hematopoietic cells Desponts, Caroline 01 June 2006 (has links) The principal isoform of Src homology (SH) 2-domain containing 5' inositol phosphatase protein 1 (SHIP) is a 145kDa protein primarily expressed by cells of the hematopoietic compartment. The enzymatic activity of SHIP is responsible for hydrolyzing the 5' phosphate of phosphatidylinositol-3,4,5-trisphosphate (PI(3,4,5)P3), and thereby preventing the recruitment of pleckstrin homology domain containing effector proteins. Furthermore, SHIP contains protein-protein interaction domains, such as an SH2 domain, two NPXY and several proline-rich motifs. All of these different domains endow SHIP with the capacity to impact signaling pathways important for proliferation, survival, differentiation and activation. Therefore, we hypothesized that SHIP-deficiency could result in the loss of hematopoietic cell homeostasis and functionTo this verify this hypothesis, we first studied the effect of SHIP ablation on hematopoietic stem cell (HSC) proliferation, survival, function and hom ing. Most interestingly we observed that SHIP impacts HSC homeostasis and their ability to home appropriately to the bone marrow. Then, since SHIP was shown to be activated after engagement of the c-mpl receptor by its ligand, thrombopoietin, we studied the impact of SHIP deletion on the function of megakaryocytes, the major target cell of that cytokine. We found that SHIP is also important for homeostasis of the megakaryocyte compartment. Thirdly, we studied the role of SHIP in natural killer (NK) cells biology. We observed that F4 generation SHIP-/- mice have increased NK cells in their spleen and that these cells exhibit a disrupted receptor repertoire. We verified the hypothesis that SHIP helps shape the receptor repertoire of NK cells, mainly through regulation of cell survival and proliferation. Also included, is a study on the role of a SHIP isoform lacking the SH2-domain, called stem cell-SHIP (s-SHIP) in the biology of embryonic stem (ES) cells. To date, this isoform i s expressed by stem/progenitor cells and not by normal differentiated cells. Due to its specific expression pattern, s-SHIP has the potential to have an important role in stem cell biology. Embryonic stem cell Hematopoietic stem cell NK cells Megakaryocytes Hematopoiesis S-SHIP American Studies Arts and Humanities

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