Global ETD Search

1	Mechanism of cell adhesion at the midbrain-hindbrain neural plate in the teleost Danio rerio Kadner, Diana 30 July 2009 (has links) (PDF) The correct development of multicellular organisms is tightly regulated by intrinsic and extrinsic factors at specific time points. Disturbance on any level of these multiple processes may result in drastic phenotypes or eventually death of the organism. The midbrain-hindbrain boundary (also termed isthmic organizer) is a region of high interest as well in early as also in later development. The isthmic region carries organizer identity by the expression and subsequent release of FGF8. False patterning events of this region in early developmental stages would therefore display dramatic results over time. As it has been shown that the midbrain-hindbrain boundary (mhb) in the zebrafish is a compartment (or lineage restriction) boundary I tried to understand the underlying molecular mechanism for its correct establishment. In this work I focused both on embryological, molecular and genetic means to characterize involved molecules and mechanisms. In the first part of the thesis I followed in vivo cell transplantation assays, having started with an unbiased one. Cells of either side the mhb were challenged with this boundary by bringing them into direct cell contact with their ectopic counterpart. In a biased approach, cells overexpressing mRNA of specific candidate genes were transplanted and their clonal distribution in host embryos was analyzed. In the second part of the thesis I started interfering with specific candidate genes by transiently knocking down their protein translation. The adhesion molecules of the Eph/ephrin class had been shown to restrict cell mixing and thereby creating compartment boundaries in other tissues, such as the hindbrain, in the zebrafish and other organisms. Additionally, we generated several stable genetic mutant lines in cooperation with the Tilling facility at the Max-Planck-Institute. The only acquired potential null mutant ephrinB2bhu2971 was analyzed and characterized further. I observed that a knock down or knock out of only one of the ephrinB2 ligands does not seem to be sufficient for a loss of compartment boundary formation. The combinatory approach of blocking translation of EphrinB2a in ephrinB2bhu2971 mutants gave very complex and interesting phenotypes, which need to be investigated further. midbrain-hindbrain boundary MHB/isthmic organizer zebrafish Tilling Eph/ephrin Mittel-Hinterhirngrenze MHB/Isthmus Zebrafisch Tilling Eph/ephrin ddc:570 rvk:WG 2100
2	Mechanism of cell adhesion at the midbrain-hindbrain neural plate in the teleost Danio rerio Kadner, Diana 09 June 2009 (has links) The correct development of multicellular organisms is tightly regulated by intrinsic and extrinsic factors at specific time points. Disturbance on any level of these multiple processes may result in drastic phenotypes or eventually death of the organism. The midbrain-hindbrain boundary (also termed isthmic organizer) is a region of high interest as well in early as also in later development. The isthmic region carries organizer identity by the expression and subsequent release of FGF8. False patterning events of this region in early developmental stages would therefore display dramatic results over time. As it has been shown that the midbrain-hindbrain boundary (mhb) in the zebrafish is a compartment (or lineage restriction) boundary I tried to understand the underlying molecular mechanism for its correct establishment. In this work I focused both on embryological, molecular and genetic means to characterize involved molecules and mechanisms. In the first part of the thesis I followed in vivo cell transplantation assays, having started with an unbiased one. Cells of either side the mhb were challenged with this boundary by bringing them into direct cell contact with their ectopic counterpart. In a biased approach, cells overexpressing mRNA of specific candidate genes were transplanted and their clonal distribution in host embryos was analyzed. In the second part of the thesis I started interfering with specific candidate genes by transiently knocking down their protein translation. The adhesion molecules of the Eph/ephrin class had been shown to restrict cell mixing and thereby creating compartment boundaries in other tissues, such as the hindbrain, in the zebrafish and other organisms. Additionally, we generated several stable genetic mutant lines in cooperation with the Tilling facility at the Max-Planck-Institute. The only acquired potential null mutant ephrinB2bhu2971 was analyzed and characterized further. I observed that a knock down or knock out of only one of the ephrinB2 ligands does not seem to be sufficient for a loss of compartment boundary formation. The combinatory approach of blocking translation of EphrinB2a in ephrinB2bhu2971 mutants gave very complex and interesting phenotypes, which need to be investigated further. info:eu-repo/classification/ddc/570 ddc:570
3	The role of pou2/spiel-ohne-grenzen (spg) in brain and endoderm development of the zebrafish, Danio rerio Reim, Gerlinde 04 August 2003 (has links) (PDF) The central theme of development, how cells are organized into functional structures and assembled into whole organisms, is addressed by developmental biology. One important feature of embryonic development is pattern formation, which is the generation of a particular arrangement of cells in three-dimensional space at a given point of time. Central to this work is the model system of the zebrafish, Danio rerio. The aim of the first part of this study was to try to understand how a distinct part of the embryonic brain called midbrain-hindbrain boundary (MHB), a region that acts as an organizer for the adjacent brain regions, is established in vertebrates. spiel-ohne-grenzen (spg) is one mutant which interferes with MHB development. Here, I addressed the role of pou2 in brain development by molecular, phenotypical and functional analysis. By genetic complementation and mapping I could elucidate the molecular nature of this mutant and found that the pou2 gene encoding the POU domain transcription factor is affected in spg mutant embryos. By chromosomal syntenic conservation, phylogenetic sequence comparison, and expression and functional data I imply that pou2 is the orthologue of the mammalian Oct4 (Pou5F1) gene. I find by detailed expression and transplantation analysis that pou2 is cell autonomously required within the neuroectoderm to activate genes of the MHB and hindbrain primordium, like pax2.1, wnt1, gbx2 or krox20. By gain-of-function experiments I demonstrate that pou2 synergizes with Fgf8 signaling in order to activate particularly the hindbrain primordium. Since pou2 is already provided to the embryo by the mother, I generated embryos which lack maternal and zygotic pou2 function (MZspg) to reveal a possible earlier than neuroectodermal role of pou2. In the second part of this work I demonstrate that pou2 is a key factor controlling endoderm differentiation. By expression and gain-of-function analysis I suggest a cell autonomous function for Pou2 in the first step of endodermal differentiation. By gain-of-function experiments involving the gene encoding the HMG transcription factor Casanova (Cas) I show that both Cas and Pou2 are necessary to activate expression of the endodermal differentiation marker sox17 in a mutually dependent way, and that the ability of Cas to ectopically induce sox17 strictly requires Pou2. I conclude that both maternal and zygotic pou2 function is necessary for commitment of endodermal progenitor cells to differentiate into endodermal precursor cells. Endoderm Kompetenz Mittel-Hinterhirn Grenze Musterbildung fgf8 maternal-zygotische Funktion pou2 competence endoderm fgf8 maternal-zygotic function midbrain-hindbrain boundary pattern formation pou2 ddc:32 rvk:WW 2620 Entoderm Gehirn Hinterhirn Maternaler Effekt Mittelhirn Molekularembryologie Musterbildung Pou-Proteinfamilie Zebrabärbling
4	Neuromeric organization of the midbrain-hindbrain boundary region in zebrafish Langenberg, Tobias 14 November 2004 (has links) (PDF) The neuromeric concept of brain formation has become a well-established model to explain how order is created in the developing vertebrate central nervous system. The most important feature of neuromeres is their compartmentalization on the cellular level: Each neuromere comprises a lineage-restricted population of cells that does not intermingle with cells from neighboring compartments. The units of the vertebrate hindbrain, the rhombomeres, serve as the best-studied examples of neuromeres. Here, the lineage restriction mechanism has been found to function on the basis of differentially expressed adhesion molecules. To date, hard evidence for the existence of other lineage restricted regions in more anterior parts of the brain is still scarce. The focus of this study is the midbrain-hindbrain boundary (mhb) region, where the juxtaposition of the mesencephalon and metencephalon gives rise to a signaling center, termed the midbrain-hindbrain or isthmic organizer. Evidence for lineage restriction boundaries in the mhb region is still controversial, with some very recent studies supporting the existence of a lineage boundary between the mesencephalon and metencephalon and others rejecting this. Here, I present data strongly supporting the existence of a compartment boundary between the posterior midbrain and anterior hindbrain territory. I base this proposition on cell-tracing experiments with single cell resolution. By connecting the traces to a molecular midbrain marker, I establish a link between cell fate and behavior. In the second part, I present a novel tissue explant method for the zebrafish that has the potential to serve numerous developmental studies, especially imaging of so far inaccessible regions of the embryo. Mittel-Hinterhirn Grenze Neuromere Organisator Segment Zebrafisch Zellverhalten lineage restriction midbrain-hindbrain boundary neuromeres organizer segments zebrafish ddc:570 rvk:WX 6500 Gewebekultur Grenze Hinterhirn Methode Mittelhirn Morphogenese Neuromerie Zebrabärbling
5	Neuromeric organization of the midbrain-hindbrain boundary region in zebrafish Langenberg, Tobias 10 December 2004 (has links) The neuromeric concept of brain formation has become a well-established model to explain how order is created in the developing vertebrate central nervous system. The most important feature of neuromeres is their compartmentalization on the cellular level: Each neuromere comprises a lineage-restricted population of cells that does not intermingle with cells from neighboring compartments. The units of the vertebrate hindbrain, the rhombomeres, serve as the best-studied examples of neuromeres. Here, the lineage restriction mechanism has been found to function on the basis of differentially expressed adhesion molecules. To date, hard evidence for the existence of other lineage restricted regions in more anterior parts of the brain is still scarce. The focus of this study is the midbrain-hindbrain boundary (mhb) region, where the juxtaposition of the mesencephalon and metencephalon gives rise to a signaling center, termed the midbrain-hindbrain or isthmic organizer. Evidence for lineage restriction boundaries in the mhb region is still controversial, with some very recent studies supporting the existence of a lineage boundary between the mesencephalon and metencephalon and others rejecting this. Here, I present data strongly supporting the existence of a compartment boundary between the posterior midbrain and anterior hindbrain territory. I base this proposition on cell-tracing experiments with single cell resolution. By connecting the traces to a molecular midbrain marker, I establish a link between cell fate and behavior. In the second part, I present a novel tissue explant method for the zebrafish that has the potential to serve numerous developmental studies, especially imaging of so far inaccessible regions of the embryo. info:eu-repo/classification/ddc/570 ddc:570
6	Patterning of the embryonic vertebrate Brain in Response to Fibroblast Growth Factor Signaling / Fgf-abhängige Musterbildungsprozesse in der embryonalen Entwicklung des Wirbeltiergehirns Raible, Florian 23 June 2003 (has links) (PDF) The term &quot;pattern formation&quot; refers to the process by which order unfolds in development. The present thesis deals with a particular aspect of molecular pattern formation during vertebrate embryogenesis. The model system in the focus of this study is the zebrafish, Danio rerio. In the early developmental phases of the zebrafish, Fibroblast growth factors (Fgfs) are involved in the molecular patterning of various tissues, including two regions of the brain, the forebrain and the midbrain-hindbrain region, affecting cellular processes as diverse as cell proliferation, differentiation, and axonal targeting. The goal of this study was to better understand the mechanisms by which Fgf signaling regulates pattern formation and embryogenesis. I addressed this question on several levels, investigating the extent of intracellular signaling (MAPK activation) relative to sources of Fgf expression, and the transcriptional responses of cells to Fgf signaling during embryogenesis. By a macroarray analysis, I identified putative transcriptional targets of Fgf signaling in late gastrulation, providing a set of molecules that are likely to act as functional players in relaying the patterning information encoded by Fgf signals. Among those are the secreted signaling molecules Chordin and Wnt8, as well as Isthmin, a novel secreted molecule that I found capable to interfere with anterior embryonic patterning. In addition, I identified two ETS domain transcription factors, Erm and Pea3, which constitute bona fide integrators of FgfR signaling. By gain- and loss-of-function studies, I demonstrate that transcript levels of erm and pea3 are tightly regulated by Fgf signaling. Detailed analysis of the expression patterns of erm and pea3 along with other Fgf target genes also provides evidence for a differential read-out of Fgf concentration in the embryo, consistent with a role of Fgf as a vertebrate morphogen. The discovery of novel molecular components downstream of Fgf receptor activity paves a way to characterize previously unknown or underestimated developmental roles of Fgfs in the molecular patterning of the forebrain, the eye and parts of the neural crest. Danio rerio Embryo Fgf Fibroblasten-Wachstumsfaktoren Gehirn MHG Macro-Array Mittel-Hinterhirn-Grenze Musterbildung Screen Signaltransduktion Zebrafisch Zielgene Danio rerio Fgf Fibroblast growth factors MHB brain embryo macro-array midbrain-hindbrain boundary pattern formation screen signal transduction target genes zebrafish ddc:32 rvk:WW 2400 Embryogenese Fibroblastenwachstumsfaktor Gehirn Musterbildung Signaltransduktion Zebrabärbling
7	Patterning of the embryonic vertebrate Brain in Response to Fibroblast Growth Factor Signaling Raible, Florian 27 June 2003 (has links) The term &quot;pattern formation&quot; refers to the process by which order unfolds in development. The present thesis deals with a particular aspect of molecular pattern formation during vertebrate embryogenesis. The model system in the focus of this study is the zebrafish, Danio rerio. In the early developmental phases of the zebrafish, Fibroblast growth factors (Fgfs) are involved in the molecular patterning of various tissues, including two regions of the brain, the forebrain and the midbrain-hindbrain region, affecting cellular processes as diverse as cell proliferation, differentiation, and axonal targeting. The goal of this study was to better understand the mechanisms by which Fgf signaling regulates pattern formation and embryogenesis. I addressed this question on several levels, investigating the extent of intracellular signaling (MAPK activation) relative to sources of Fgf expression, and the transcriptional responses of cells to Fgf signaling during embryogenesis. By a macroarray analysis, I identified putative transcriptional targets of Fgf signaling in late gastrulation, providing a set of molecules that are likely to act as functional players in relaying the patterning information encoded by Fgf signals. Among those are the secreted signaling molecules Chordin and Wnt8, as well as Isthmin, a novel secreted molecule that I found capable to interfere with anterior embryonic patterning. In addition, I identified two ETS domain transcription factors, Erm and Pea3, which constitute bona fide integrators of FgfR signaling. By gain- and loss-of-function studies, I demonstrate that transcript levels of erm and pea3 are tightly regulated by Fgf signaling. Detailed analysis of the expression patterns of erm and pea3 along with other Fgf target genes also provides evidence for a differential read-out of Fgf concentration in the embryo, consistent with a role of Fgf as a vertebrate morphogen. The discovery of novel molecular components downstream of Fgf receptor activity paves a way to characterize previously unknown or underestimated developmental roles of Fgfs in the molecular patterning of the forebrain, the eye and parts of the neural crest. info:eu-repo/classification/ddc/32 ddc:32
8	The role of pou2/spiel-ohne-grenzen (spg) in brain and endoderm development of the zebrafish, Danio rerio Reim, Gerlinde 12 August 2003 (has links) The central theme of development, how cells are organized into functional structures and assembled into whole organisms, is addressed by developmental biology. One important feature of embryonic development is pattern formation, which is the generation of a particular arrangement of cells in three-dimensional space at a given point of time. Central to this work is the model system of the zebrafish, Danio rerio. The aim of the first part of this study was to try to understand how a distinct part of the embryonic brain called midbrain-hindbrain boundary (MHB), a region that acts as an organizer for the adjacent brain regions, is established in vertebrates. spiel-ohne-grenzen (spg) is one mutant which interferes with MHB development. Here, I addressed the role of pou2 in brain development by molecular, phenotypical and functional analysis. By genetic complementation and mapping I could elucidate the molecular nature of this mutant and found that the pou2 gene encoding the POU domain transcription factor is affected in spg mutant embryos. By chromosomal syntenic conservation, phylogenetic sequence comparison, and expression and functional data I imply that pou2 is the orthologue of the mammalian Oct4 (Pou5F1) gene. I find by detailed expression and transplantation analysis that pou2 is cell autonomously required within the neuroectoderm to activate genes of the MHB and hindbrain primordium, like pax2.1, wnt1, gbx2 or krox20. By gain-of-function experiments I demonstrate that pou2 synergizes with Fgf8 signaling in order to activate particularly the hindbrain primordium. Since pou2 is already provided to the embryo by the mother, I generated embryos which lack maternal and zygotic pou2 function (MZspg) to reveal a possible earlier than neuroectodermal role of pou2. In the second part of this work I demonstrate that pou2 is a key factor controlling endoderm differentiation. By expression and gain-of-function analysis I suggest a cell autonomous function for Pou2 in the first step of endodermal differentiation. By gain-of-function experiments involving the gene encoding the HMG transcription factor Casanova (Cas) I show that both Cas and Pou2 are necessary to activate expression of the endodermal differentiation marker sox17 in a mutually dependent way, and that the ability of Cas to ectopically induce sox17 strictly requires Pou2. I conclude that both maternal and zygotic pou2 function is necessary for commitment of endodermal progenitor cells to differentiate into endodermal precursor cells. info:eu-repo/classification/ddc/32 ddc:32

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