Global ETD Search

1	Crucial transcription factors in endoderm and embryonic gut development are expressed in gut-like structures from mouse ES cells Matsuura, Rie, Kogo, Hiroshi, Ogaeri, Takunori, Miwa, Takashi, Kuwahara, Masaki, Kanai, Yoshiakira, Nakagawa, Takumi, Kuroiwa, Atsushi, Fujimoto, Toyoshi, Torihashi, Shigeko, 鳥橋, 茂子 03 1900 (has links) No description available. embryonic stem cell embryoid body transcription factors development gastrointestinal motility
2	Directed differentiation of mouse embryonic stem cells to haematopoietic lineages using EPL induction Frances Harding Unknown Date (has links) No description available.
3	VEGFR-2 in Endothelial Differentiation and Vascular Organization Edholm, Dan January 2008 (has links) The cardiovascular system is the first functional organ to develop during embryogenesis. As the embryo reaches above a certain size, passive diffusion of gases and nutrients is no longer compatible with efficient growth. During embryogenesis, endothelial progenitor cells (angioblasts) are recruited from the primitive streak mesoderm and instructed to express vascular endothelial growth factor receptor-2 (VEGFR-2). This thesis examines the roles played by VEGFR-2 in the events through which a subpopulation of embryonic stem (ES) cells differentiate into endothelial cells and form the vasculature. We show that ES cells gene targeted for VEGFR-2 (flk1-/-) develop immature endothelial cells (ECs), precursors, when differentiated in vitro as embryoid bodies (EBs). The flk1-/- ECs are unresponsive to VEGF-stimulation and consistently fail to form vessels. However, when co-cultured with wild type ES cells in chimeric EBs, flk1-/- endothelial precursors are guided by wild type ECs to form transient, chimeric vascular structures. Use of lentivirus in an add-back approach allowed reconstitution of VEGFR-2 expression in flk1-/- ES cells, and rescue of vasculogenesis and sprouting angiogenesis. We propose that recruitment to the endothelial lineage is not dependent on VEGFR-2, although this receptor tyrosine kinase appears indispensible for EC integrity, survival and for differentation of endothelial precursors into mature ECs formating a stable vasculature. Neuropilin-1 (NRP1) and heparan sulfate proteoglycans (HSPGs) function as co-receptors for VEGFs. The co-receptors influence, qualitatively and quantitatively, the intracellular signal relayed by VEGFR-2 but it is unclear how. We examined the contribution of NRP1 to VEGFR-2 signaling in EB cultures, in zebrafish and in mice. Only NRP1-binding VEGFs were able to promote sprouting angiogenesis and formation of properly branched vascular tubes, supported by pericytes. Downstream of VEGFR-2/NRP1 activation, we identified recruitment of p38MAPK in signal transduction regulating sprouting angiogenesis. Molecular medicine Embryonic stem VEGFR-2 Flk1 KDR VEGF vasculogenesis angiogenesis embryoid body Molekylärmedicin
4	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
5	Biophysical and biochemical control of three-dimensional embryonic stem cell differentiation and morphogenesis Kinney, Melissa 08 June 2015 (has links) Stem cell differentiation is regulated by the complex interplay of multiple parameters, including adhesive intercellular interactions, cytoskeletal and extracellular matrix remodeling, and gradients of agonists and antagonists that individually and collectively vary as a function of spatial locale and temporal stages of development. Directed differentiation approaches have traditionally focused on the delivery of soluble morphogens and/or the manipulation of culture substrates in two-dimensional, monolayer cultures, with the objective of achieving large yields of homogeneously differentiated cells. However, a more complete understanding of stem cell niche complexity motivates tissue engineering approaches to inform the development of physiologically relevant, biomimetic models of stem cell differentiation. The capacity of pluripotent stem cells to simultaneously differentiate toward multiple tissue-specific cell lineages has prompted the development of new strategies to guide complex, three-dimensional morphogenesis of functional tissue structures. The objective of this project was to characterize the spatiotemporal dynamics of stem cell biophysical characteristics and morphogenesis, to inform the development of ESC culture technologies to present defined and tunable cues within the three-dimensional spheroid microenvironment. The hypothesis was that the biophysical and biochemical cues present within the 3D microenvironment are altered in conjunction with morphogenesis as a function of stem cell differentiation stage. Understanding biochemical and physical tissue morphogenesis, including the relationships between remodeling of cytoskeletal elements and intercellular adhesions, associated developmentally relevant signaling pathways, and the physical properties of the EB structure together elucidate fundamental cellular interactions governing embryonic morphogenesis and cell specification. Together, this project has established a foundation for controlling, characterizing, and systematically perturbing aspects of stem cell microenvironments in order to guide the development of complex, functional tissue structures for regenerative therapies. BMP-4 Embryonic stem cells Differentiation Morphogenesis Spheroid Embryoid body Regenerative medicine Tissue engineering Transport Biomechanics
6	Modulation of Angiogenesis by Laminins and Heparan Sulfate Jakobsson, Lars January 2007 (has links) <p>Blood vessels transport blood with essential nutrients and oxygen to the cells in our body. In a healthy adult, formation of new vessels (angiogenesis) occurs only in case of tissue repair and growth. Physiological angiogenesis requires precise regulation of multiple signaling components, a process which is deregulated in a number of pathological conditions, such as cancer. This thesis is focused on the role of laminins, heparan sulfate proteoglycans (HSPGs) and vascular endothelial growth factor (VEGF)-A in regulation of vascular development and angiogenesis. As a model, we have used embryonic stem cells that differentiate to form blood vessels in a manner faithfully recapitulating the <i>in vivo</i> processes. </p><p>We show that the basement membrane (BM) protein laminin-111 promotes maturation of endothelial cells in the presence of fibroblast growth factor-2, a known endothelial cell mitogen. However, embryonic stem cells are able to differentiate into endothelial cells also in the absence of laminin deposition in the vascular BM. Sprouting angiogenesis, induced by VEGF-A, is also not strictly dependent on laminin deposition. On the other hand, in the absence of laminins, vessels are enlarged. These data suggest an important role for laminins in regulation of the vessel diameter.</p><p>We also show that HSPGs serve as coreceptors for VEGF-A to regulate vascular development. The mode of presentation of HSPGs, <i>in</i> <i>cis</i> (on the endothelial cell) or <i>in</i> <i>trans</i> (on an adjacent cell such as pericytes), is critical in regulation of VEGF receptor-2 activation and stimulation of vascular development. Binding of VEGF-A to HSPGs <i>in</i> <i>trans</i> leads to accumulation of activated VEGFR-2 in endothelial cells and to prolonged signaling. This demonstrates a potential role for HSPGs in regulation of receptor trafficking and signaling kinetics, with possible implications also for other HS-binding ligand/receptor systems.</p> Molecular medicine Embryonic stem heparan sulfate laminin basement membrane VEGFR-2 VEGF endothelial cell signaling angiogenesis vasculogenesis embryoid body Molekylärmedicin
7	Modulation of Angiogenesis by Laminins and Heparan Sulfate Jakobsson, Lars January 2007 (has links) Blood vessels transport blood with essential nutrients and oxygen to the cells in our body. In a healthy adult, formation of new vessels (angiogenesis) occurs only in case of tissue repair and growth. Physiological angiogenesis requires precise regulation of multiple signaling components, a process which is deregulated in a number of pathological conditions, such as cancer. This thesis is focused on the role of laminins, heparan sulfate proteoglycans (HSPGs) and vascular endothelial growth factor (VEGF)-A in regulation of vascular development and angiogenesis. As a model, we have used embryonic stem cells that differentiate to form blood vessels in a manner faithfully recapitulating the in vivo processes. We show that the basement membrane (BM) protein laminin-111 promotes maturation of endothelial cells in the presence of fibroblast growth factor-2, a known endothelial cell mitogen. However, embryonic stem cells are able to differentiate into endothelial cells also in the absence of laminin deposition in the vascular BM. Sprouting angiogenesis, induced by VEGF-A, is also not strictly dependent on laminin deposition. On the other hand, in the absence of laminins, vessels are enlarged. These data suggest an important role for laminins in regulation of the vessel diameter. We also show that HSPGs serve as coreceptors for VEGF-A to regulate vascular development. The mode of presentation of HSPGs, in cis (on the endothelial cell) or in trans (on an adjacent cell such as pericytes), is critical in regulation of VEGF receptor-2 activation and stimulation of vascular development. Binding of VEGF-A to HSPGs in trans leads to accumulation of activated VEGFR-2 in endothelial cells and to prolonged signaling. This demonstrates a potential role for HSPGs in regulation of receptor trafficking and signaling kinetics, with possible implications also for other HS-binding ligand/receptor systems. Molecular medicine Embryonic stem heparan sulfate laminin basement membrane VEGFR-2 VEGF endothelial cell signaling angiogenesis vasculogenesis embryoid body Molekylärmedicin
8	Effects of hydrodynamic culture on embryonic stem cell differentiation: cardiogenic modulation Sargent, Carolyn Yeago 07 July 2010 (has links) Stem and progenitor cells are an attractive cell source for the treatment of degenerative diseases due to their potential to differentiate into multiple cell types and provide large cell yields. Thus far, however, clinical applications have been limited due to inefficient differentiation into desired cell types with sufficient yields for adequate tissue repair and regeneration. The ability to spontaneously aggregate in suspension makes embryonic stem cells (ESCs) amenable to large-scale culture techniques for the production of large yields of differentiating cell spheroids (termed embryoid bodies or EBs); however, the introduction of hydrodynamic conditions may alter differentiation profiles within EBs and should be methodically examined. The work presented here employs a novel, laboratory-scale hydrodynamic culture model to systematically interrogate the effects of ESC culture hydrodynamics on cardiomyocyte differentiation through the modulation of a developmentally-relevant signaling pathway. The fluidic environment was defined using computational fluid dynamic modeling, and the effects of hydrodynamic conditions on EB formation, morphology and structure were assessed. Additionally, EB differentiation was examined through gene and protein expression, and indicated that hydrodynamic conditions modulate differentiation patterns, particularly cardiogenic lineage development. This work illustrates that mixing conditions can modulate common signaling pathways active in ESC differentiation and suggests that differentiation may be regulated via bioprocessing parameters and bioreactor design. Embryonic stem cells Embryoid body Hydrodynamic Bioprocessing Differentiation Cardiomyocyte Heart cells Degeneration (Pathology) Hydrodynamics Embryonic stem cells Research
9	Stem cell function and organ development : analysis of Lhx2 function in hematopoietic stem cells and eye development / Stamcellsfunktion och organutveckling : studier av blodstamceller och ögonutveckling Dahl, Lina January 2010 (has links) When a multicellular organism suffers damages to tissues/organs it heals itself by either substituting the lost cellular matrix by scar formation or by regenerating the lost tissue. Regeneration likely occurs by a recapitulation of the developmental process that formed the organ. Many processes regulating organ development are based on epithelial-mesenchymal interactions and a strict control of organ specific stem/progenitor cells. Elucidation of the molecular basis of these processes is therefore vital in order to develop novel therapies in regenerative medicine. The LIM homebox gene Lhx2 is interesting in this context since Lhx2 has been shown to be important for the formation of several organs by regulating epithelial-mesenchymal interactions and progenitor cell function. Targeted inactivation of Lhx2 leads to a lethal anemia due to malformed liver and severe neural abnormalities such as hypoplasia of the forebrain and anophtalmia. Thus, elucidation of the mechanisms of the function of Lhx2 in different organ systems would give important insights into the molecular mechanisms regulating epithelial-mesenchymal interactions and stem/progenitor cell function. To elucidate the function of Lhx2 in the hematopoietic system Lhx2 was initially expressed in hematopoietic progenitor cells derived from ES cells differentiated in vitro using retroviral vectors. This approach led to the generation of hematopoietic stem cell (HSC)-like cell lines suggesting that Lhx2 could impact HSC function. However neither the specificity nor the efficiency of the Lhx2-induced phenotype could be determined using this approach. To be able to elucidate the function of Lhx2 in the hematopoietic system, an ES cell line with inducible Lhx2 expression was generated. Lhx2 expression induces self-renewal of a distinct hematopoietic progenitor cell from which HSC-like cell lines were established. Down-regulation of Lhx2 in these HSC-like cell lines leads to a rapid loss of stem cell character, providing a good model to study the molecular function of Lhx2 in hematopoietic stem/progenitor cells. A global gene expression analysis was performed comparing the Lhx2+ stem cell population to the Lhx2- differentiated progeny. This approach identified genes putatively linked to self-renewal/differentiation of HSCs. A considerable proportion of the genes showed an overlapping gene expression pattern with Lhx2 expression in tissue of non-hematopoietic origin suggesting that Lhx2 function in stem/progenitor cells partly overlap with Lhx2 function during organ development. In order to define other Lhx2-dependent progenitor cell populations and to generate a tool to analyze the function of Lhx2 in organ development a new transgenic mouse model was generated. By using a specific part of the Lhx2 promoter to drive expression of Cre recombinase in vivo (Lhx2-Cre mice) we have been able to define the first eye committed progenitor cells in the forebrain. By using the Lhx2-Cre mice it will be possible to distinguish the function of genes during eye development from their function in the patterning of the forebrain e.g. the eye field transcription factors. Conditional inactivation of Lhx2 in these eye specific progenitor cells causes an immediate developmental arrest. The transgene is also active in Lhx2-/- embryonic forebrain, but re-expression of Lhx2 in Lhx2-/- progenitor cells only promote formation of retinal pigment epithelium cells. Analysis of genes expressed by the Lhx2+ stem cell population allowed us to define novel genes putatively linked to Lhx2 function in eye development. Thus, we have defined the progenitor cells in the forebrain committed to eye development and the expansion and patterning of these progenitors are dependent on Lhx2. Although commitment to eye development is Lhx2-independent, Lhx2 might be important for the acquisition of the oligopotent fate of these progenitor cells. Lhx2 hematopoietic system hematopoietic stem cell progenitor embryonic stem cell embryoid body eye development forebrain eye field transcription factor
10	Estrategias para la diferenciación in vitro de células ES de ratón a células acinares pancreáticas Rovira Clusellas, Meritxell 31 January 2007 (has links) Las patologías más importantes del páncreas exocrino, como la pancreatitis crónica (PC) o el cáncer de páncreas, representan un gran problema de salud pública en Europa. En la PC, el tejido acinar es substituido por complejos ductales. Además, es difícil mantener el fenotipo diferenciado de las células acinares en cultivo ya que sufren una transdiferenciación acinar-ductal.Las células madre embrionarias (ES) de ratón han sido utilizadas en la última década para generar in vitro células completamente diferenciadas de varios linajes celulares. No obstante, la capacidad de las células ES a diferenciarse a tipos celulares de origen endodérmico es muy limitada. El objetivo principal de este proyecto ha consistido en desarrollar estrategias para diferenciar células ES de ratón a células pancreáticas acinares con una elevada eficiencia mediante 1) la optimización de las condiciones de cultivo con tal de activar vías de señalización implicadas en el desarrollo/diferenciación pancreáticas; 2) la sobreexpresión de factores transcripcionales maestros utilizando vectores virales con el fin de recapitular específicamente un programa de diferenciación acinar; 3) la selección genética de las células comprometidas al linaje acinar con el objetivo de purificar las células acinares diferenciadas.Mediante la integración de estos abordajes, hemos conseguido aislar células que comparten características fenotípicas con células acinares inmaduras según la expresión de marcadores de diferenciación y la respuesta funcional a secretagogos. / Exocrine pancreatic diseases such as chronic pancreatitis (PC) or pancreatic cancer are major health issues in Europe. In CP, the acinar tissue is substituted by ductal complexes. In addition, it is difficult to maintain the differentiated phenotype of the acinar cells in culture as within few days an acinar-ductal transdifferentiation takes place.In the last decade, mouse embryonic stem cells (mES) have been used to generate differentiated cells of a variety of cellular lineages in vitro. However, the ability of ES cells to differentiate into endodermal lineages is limited. The main objective of this project has focused on the development of strategies to differentiate mES to pancreatic acinar cells with high efficiency by means of: 1) Optimization of cell culture conditions to activate signalling pathways involved in pancreatic differentiation/development; 2) the overexpression of master transcription factors involved in pancreas development using viral vectors in order to recapitulate specific acinar differentiation program; 3) the genetic selection of cells committed to the acinar linage in order to purify the differentiated cells.The integration of these different strategies allowed us to isolate cells that share phenotypic features with immature acinar cells according to the expression of differentiation markers and the functional response to acinar secretegogues. pancreas lentivirus infection symogen granule follistatin digestive enzyme differentiation embryonic stem cell embryoid body acinar cell adenovirus secretion genetic selection overexpression fetal pancreatic supernatant 576 616.4

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