Global ETD Search

71	Studies of the regulation of serine protease activity in the establishment of the dorsal-ventral axis of the Drosophila embryo Cho, Yong Suk, 1970- 05 October 2010 (has links) Dorsal-ventral (DV) polarity in the Drosophila embryo is defined by spatially regulated activation of the transmembrane receptor Toll, which is uniformly distributed throughout the early embryo's plasma membrane. Ventral activation of Toll is accomplished through the local production of its activating ligand, a processed C-terminal fragment of the Spätzle protein, which is generated in the last step of a proteolytic cascade involving the sequentially-acting proteases Gastrulation Defective (GD), Snake and Easter. Pipe protein, a homologue of vertebrate glycosaminoglycan modifying enzymes, which is expressed during oogenesis in ventral follicle cells adjacent to the developing oocyte, is believed to control the ventrally restricted processing of Spätzle. pipe expression and the sulfation of its enzymatic target in the ventral follicle cells leads to the formation of a stable ventral cue, embedded in the eggshell. Recently the Pipe enzymatic target has been identified as several protein components of the vitelline membrane, the inner layer of the eggshell. Prior to this work, an important piece of information missing from our understanding of Drosophila DV patterning was the identity of the initial step in the protease cascade that requires Pipe activity. Here, I show that the processing of Snake is independent of Pipe activity, while the processing of Easter requires Pipe function, indicating that Easter processing by Snake is the key proteolytic step that is controlled by Pipe activity and presumably the first cleavage event that is spatially regulated. A second key gap in our understanding of Drosophila embryonic DV patterning concerned the role of GD in the protease cascade. While GD is the protease that cleaves and activates Snake, the existence of two distinct classes of complementing gd alleles has suggested that GD provides another, distinct function. Investigations described here indicate that the second function of GD is to promote the ability of activated Snake to process Easter, independent of its Snake-processing function. Finally, I provide evidence for the formation of protein complexes containing various components of the serine protease cascade, which suggest that conformational changes in the complexes, which act to promote productive interactions between the proteins, are an important aspect of their activation. / text Drosophila Axis establishment Pipe Serine protease Drosophila embryo Dorsal-ventral polarity Toll receptor Spätzle protein Gastrulation Defective
72	Towards an Understanding of Zebrafish Epiboly: The Characterization of the Epiboly Initiation Mutant Eomesodermin A Du, Susan 31 December 2010 (has links) How cell movements are coordinated during morphogenesis is not well understood. We focus on epiboly, which describes the thinning and spreading of a multilayered cell sheet. The first phase of epiboly involves the doming of the yolk cell up into the overlying blastoderm. We previously showed that over-expression of a dominant– negative eomesodermin a construct inhibits doming. Here I report my analysis of embryos lacking both maternal and zygotic Eomesodermin A (MZeomesa). eomesafh105 mutant embryos (1) exhibit a doming delay, (2) have defective yolk cell microtubules, (3) have tightly packed deep cells with more bleb – like protrusions and (4) express early endoderm markers abnormally. Despite these phenotypes, the majority of MZeomesa embryos are able to complete epiboly and form endodermal derivatives. In both Xenopus and mice, Eomesodermin has also been implicated in the regulation of gastrulation movements and cell fate specification, suggesting a conserved role for Eomesodermin throughout vertebrate development. Zebrafish Epiboly Morphogenesis Gastrulation Eomesodermin A T-box transcription factor Endoderm Microtubules yolk cell doming 0379 0307 0472
73	Towards an Understanding of Zebrafish Epiboly: The Characterization of the Epiboly Initiation Mutant Eomesodermin A Du, Susan 31 December 2010 (has links) How cell movements are coordinated during morphogenesis is not well understood. We focus on epiboly, which describes the thinning and spreading of a multilayered cell sheet. The first phase of epiboly involves the doming of the yolk cell up into the overlying blastoderm. We previously showed that over-expression of a dominant– negative eomesodermin a construct inhibits doming. Here I report my analysis of embryos lacking both maternal and zygotic Eomesodermin A (MZeomesa). eomesafh105 mutant embryos (1) exhibit a doming delay, (2) have defective yolk cell microtubules, (3) have tightly packed deep cells with more bleb – like protrusions and (4) express early endoderm markers abnormally. Despite these phenotypes, the majority of MZeomesa embryos are able to complete epiboly and form endodermal derivatives. In both Xenopus and mice, Eomesodermin has also been implicated in the regulation of gastrulation movements and cell fate specification, suggesting a conserved role for Eomesodermin throughout vertebrate development. Zebrafish Epiboly Morphogenesis Gastrulation Eomesodermin A T-box transcription factor Endoderm Microtubules yolk cell doming 0379 0307 0472
74	Endocytic Modulation of Developmental Signaling during Zebrafish Gastrulation Gerstner, Norman 18 December 2014 (has links) (PDF) Biological information processing in living systems like cells, tissues and organs critically depends on the physical interactions of molecular signaling components in time and space. How endocytic transport of signaling molecules contributes to the regulation of developmental signaling in the complex in vivo environment of a developing organism is not well understood. In a previously performed genome-wide screen on endocytosis, several genes have been identified, that selectively regulate transport of signaling molecules to different types of endosomes, without disrupting endocytosis. My PhD thesis work provides the first functional in vivo characterization of one of these candidate genes, the novel, highly conserved Rab5 effector protein P95 (PPP1R21). Cell culture studies suggest that P95 is a novel endocytic protein important to maintain the balance of distinct endosomal sub-populations and potentially regulates the sorting of signaling molecules between them (unpublished work, Zerial lab). The scientific evidence presented in this study demonstrates that zebrafish P95 is essential for early zebrafish embryogenesis. Both, knockdown and overexpression of zebrafish P95 compromise accurate morphogenetic movements and patterning of the zebrafish gastrula, showing that P95 functions during zebrafish gastrulation. P95 is functionally required to maintain signaling activity of signaling pathways that control embryonic patterning, in particular for WNT/β-catenin signaling activity. Knockdown of zebrafish P95 amplifies the recruitment of β-catenin to early endosomes, which correlates with the limitation of β-catenin to translocate to the nucleus and function as transcriptional activator. The obtained results suggest that zebrafish P95 modulates the cytoplasmic pools of β-catenin in vivo, via endosomal transport of β-catenin. In conclusion, the data presented in this thesis work provides evidence that the cytoplasm-to-nucleus shuttling of β-catenin is modulated by endocytic trafficking of β-catenin in vivo. We propose the endocytic modulation of β-catenin cytoplasm-to-nucleus trafficking as potential new mechanism to fine-tune the functional output of WNT/β-catenin signaling during vertebrate gastrulation. Zebrafisch Endozytose Signaltransduktion WNT Information Signaling Endocytosis Zebrafish Gastrulation b-catenin WNT Transport Information ddc:570 rvk:WE 5320
75	Global Analysis Of Transcriptional Control Driving Zebrafish Gastrulation Simon Wilkins Unknown Date (has links) Gastrulation, literally “formation of the gut” is ultimately an inadequate term to describe one of the most dynamic periods during vertebrate developmental biology. During gastrulation coordinated cell movements reshape the non-descript blastula into the structured gastrula and simultaneously specify the three germ layers: endoderm, mesoderm and ectoderm. The morphogenetic movements of gastrulation are highly conserved between species, but the links between their genetic and biomechanical regulation are poorly understood. The zebrafish embryo – externally hatched, optically clear and amenable to genetic manipulation – is an ideal vertebrate model in which to study both morphogenetic movements and their genetic control. This thesis provides a detailed analysis of the zebrafish Mix-type homeobox transcription factor, Mtx2, both in terms of its role in gastrulation and the molecular mechanisms regulated by Mtx2. This approach involved detailed examination of the Mtx2 loss-of-function phenotype and, subsequently, use of this phenotype as the basis for a microarray screen to identify and investigate Mtx2-dependent genes. One specific Mtx2-dependent gene, katanin-like 1 was investigated further by loss-of-function studies. Prior to this study the mtx2 gene was identified by homology, within its homeodomain, to other Mix-family transcription factors, but both its function and transcriptional targets remained unknown. Using a morpholino knockdown approach, this thesis demonstrates that Mtx2 is essential for vegetal movement (epiboly), but not specification, of the embryonic germ layers and extra-embryonic tissues during zebrafish gastrulation. The recruitment of filamentous actin (F-actin) to a punctate band at the blastoderm margin, was previously shown to be responsible for progression of epiboly. However, formation of this structure is demonstrated to be Mtx2-dependent. Microarray expression profiling of the Mtx2 loss-of-function phenotype was performed to screen for novel genes with roles in gastrulation. This approach identified Mtx2-dependent genes with roles in cytoskeletal dynamics, cell-cell adhesion and endocytosis and vesicular trafficking – processes known to be involved in morphogenetic movements. Many Mtx2-dependent genes are co-expressed with mtx2 in the extra-embryonic yolk syncytial layer (YSL), the teleost functional equivalent of mammalian visceral endoderm. The subset of Mtx2-dependent genes co-expressed with mtx2 and that contain Mtx2-binding sites within their 2kb proximal promoter represent the genes with the greatest likelihood of being direct Mtx2 transcriptional targets. A novel homologue of the microtubule severing protein Katanin, known as katanin-like 1 (katnal1) met all these conditions. Morpholino knockdown of Katnal1 demonstrates that like Mtx2, Katnal1 is essential for gastrulation in zebrafish. A cloned Katnal1mCherry fusion construct was observed to associate with microtubules, and demonstrated bi-directional trafficking around transfected mammalian cells. Analysis of the microtubule network in wild-type and morpholino injected zebrafish embryos demonstrated that remodelling of the extensive microtubule network found in the YSL and yolk cytoplasmic layer (YCL) is Katnal1-dependent. Nuclear division within the YSL and F-actin recruitment to the blastoderm margin are also Katnal1-dependent. This thesis therefore demonstrates, for the first time directly, the multiple, specific roles played by the microtubule network of the YSL/YCL. Katnal1 is highly conserved from Drosophila to mammals and is dynamically expressed during mouse gastrulation. The Mtx2 binding motif in the katnal1 2kb proximal promoter can be bound by both Mtx2 and its putative mouse homologue Mixl1. This suggests that katnal1 may also be a direct target of Mtx2. At the technical level, these results demonstrate the validity of screening for novel developmentally important genes using a zebrafish microarray-based approach, the potential of such an approach to, ab initio, identify a candidate list of transcription factor targets and confirm the utility of the zebrafish as a developmental model. At the biological level, this work collectively suggests that Mtx2 is a central regulator of the morphogenetic movement of epiboly and that Katnal1-dependent microtubule remodelling drives multiple aspects of gastrulation, potentially from Drosophila through to humans. zebrafish Gastrulation Movements Transcription Factor Microarray Vertebrate Development Vertebrate Embryogenesis Microtubule Dynamics Epiboly Developmental Biology Microtubule Biomechanical Properties
76	Molecular evolution of genes involved in neuronal development and regeneration in fish / Rivera Milla, Eric Leonardo. Unknown Date (has links) Konstanz, University, Diss., 2005.
77	Molecular Control of Morphogenesis in the Sea Urchin Embryo Martik, Megan Lee January 2015 (has links) <p>Gene regulatory networks (GRNs) provide a systems-level orchestration of an organism’s genome encoded anatomy. As biological networks are revealed, they continue to answer many questions including knowledge of how GRNs control morphogenetic movements and how GRNs evolve. Morphogenesis is a complex orchestration of movements by cells that are specified early in development. </p><p> The activation of an upstream GRN is crucial in order to orchestrate downstream morphogenetic events. In the sea urchin, activation of the endomesoderm GRN occurs after the asymmetric 4th cleavage. Embryonic asymmetric cell divisions often are accompanied by differential segregation of fate-determinants into one of two daughter cells. That asymmetric cleavage of the sea urchin micromeres leads to a differential animal-vegetal (A/V) nuclear accumulation of cell fate determinants, β-Catenin and SoxB1. Β-Catenin protein is localized into the nuclei of micromeres and activates the endomesoderm gene regulatory network, while SoxB1 is excluded from micromeres and enters the nucleus of the macromeres, the large progeny of the unequal 4th cleavage. Although nuclear localization of β-Catenin and SoxB1 shows dependence on the asymmetric cleavage, the mechanics behind the asymmetrical division has not been demonstrated. In Chapter 3, we show that micromere formation requires the small RhoGTPase, Cdc42 by directing the apical/basal orientation of the mitotic spindle at the apical cortex. By attenuating or augmenting sea urchin Cdc42 function, micromere divisions became defective and failed to correctly localize asymmetrically distributed determinants. As a consequence, cell fates were altered and multiple A/V axes were produced resulting in a “Siamese-twinning” phenotype that occurred with increasing frequency depending on the quantitative level of perturbation. Our findings show that Cdc42 plays a pivotal role in the asymmetric division of the micromeres, endomesoderm fate-determinant segregation, and A/V axis formation.</p><p> This dissertation also characterizes, at high resolution, the repertoire of cellular movements contributing to three different morphogenetic processes of sea urchin development: the elongation of gut, the formation of the primary mouth, and the migration of the small micromeres (the presumptive primordial germ cells) in the sea urchin, Lytechinus variegatus. Descriptive studies of the cellular processes during the different morphogenetic movements allow us to begin investigating their molecular control. </p><p>In Chapter 4, we dissected the series of complex events that coordinate gut and mouth morphogenesis. Until now, it was thought that lateral rearrangement of endoderm cells by convergent extension was the main contributor to sea urchin archenteron elongation and that cell divisions were minimal during elongation. We performed cell transplantations to live image and analyze a subset of labeled endoderm cells at high-resolution in the optically clear sea urchin embryo. We found that the endomesoderm cells that initially invaginate into the sea urchin blastocoel remained contiguous throughout extension, so that, if convergent extension were present, it was not a major contributor to elongation. We also found a prevalence of cell divisions throughout archenteron elongation that increased the number of cells within the gut linearly over time; however, we showed that the proliferation did not contribute to growth, and their spindle orientations were randomized during divisions and therefore did not selectively contribute to the final gut length. When cell divisions were inhibited, we saw no difference in the ability of the cells within the gut to migrate in order to elongate. Also in Chapter 4, we describe our observations of the cell biological processes underlying primary mouth formation at the end of gastrulation. Using time-lapse microscopy, photo-convertible Kaede, and an assay of the basement membrane remodeling, we describe a sequential orchestration of events that leads to the fusion of the oral ectoderm and the foregut endoderm. Our work characterizes, at higher resolution than previously recorded, the temporal sequence and repertoire of the cellular movements contributing to the length of the sea urchin larval gut and tissue fusion with the larval primary mouth.</p><p> In Chapter 5, the migration of the small micromeres to the coelomic pouches in the sea urchin embryo provides an exceptional model for understanding the genomic regulatory control of morphogenesis. An assay using the robust homing potential of these cells reveals a “coherent feed-forward” transcriptional subcircuit composed of Pax6, Six3, Eya, and Dach1 that is responsible for the directed homing mechanism of these multipotent progenitors. The linkages of that circuit are strikingly similar to a circuit involved in retinal specification in Drosophila suggesting that systems-level tasks can be highly conserved even though the tasks drive unrelated processes in different animals.</p><p> The sea urchin gene regulatory network (GRN) describes the cell fate specification of the developing embryo; however, the GRN does not describe specific cell biological events driving the three distinct sequences of cell movements. Our ability to connect the GRN to the morphogenetic events of gastrulation, primary mouth formation, and small micromere migration will provide a framework for characterizing these remarkable sequences of cell movements in the simplest of deuterostome models at an unprecedented scale.</p> / Dissertation Developmental biology Genetics Evolution & development directed cell migration gastrulation gene regulatory networks morphogenesis sea urchin transcription factors
78	Low and Moderate Prenatal Ethanol Exposures of Mice During Gastrulation or Neurulation Delays Neurobehavioral Development Schambra, Uta B., Goldsmith, Jeff, Nunley, Kevin, Liu, Yali, Harirforoosh, Sam, Schambra, Heidi M. 01 September 2015 (has links) Human and animal studies show significant delays in neurobehavioral development in offspring after prolonged prenatal exposure to moderate and high ethanol doses resulting in high blood alcohol concentration (BECs). However, none have investigated the effects of lower ethanol doses given acutely during specific developmental time periods. Here, we sought to create a mouse model for modest and circumscribed human drinking during the 3rd and 4th weeks of pregnancy.We acutely treated mice during embryo gastrulation on gestational day (GD) 7 or neurulation on GD8 with a low or moderate ethanol dose given via gavage that resulted in BECs of 107 and 177. mg/dl, respectively. We assessed neonatal physical development (pinnae unfolding, and eye opening); weight gain from postnatal day (PD) 3-65; and neurobehavioral maturation (pivoting, walking, cliff aversion, surface righting, vertical screen grasp, and rope balance) from PD3 to 17. We used a multiple linear regression model to determine the effects of dose, sex, day of treatment and birth in animals dosed during gastrulation or neurulation, relative to their vehicle controls.We found that ethanol exposure during both time points (GD7 and GD8) resulted in some delays of physical development and significant sensorimotor delays of pivoting, walking, and thick rope balance, as well as additional significant delays in cliff aversion and surface righting after GD8 treatment. We also found that treatment with the low ethanol dose more frequently affected neurobehavioral development of the surviving pups than treatment with the moderate ethanol dose, possibly due to a loss of severely affected offspring. Finally, mice born prematurely were delayed in their physical and sensorimotor development.Importantly, we showed that brief exposure to low dose ethanol, if administered during vulnerable periods of neuroanatomical development, results in significant neurobehavioral delays in neonatal mice. We thus expand concerns about alcohol consumption during the 3rd and 4th weeks of human pregnancy to include occasional light to moderate drinking. gastrulation low ethanol dose moderate ethanol dose mouse neurobehavioral delays neurulation premature birth sensorimotor development Pharmaceutical Sciences Mathematics and Statistics
79	Funktionsanalyse des Irx1-Gens / Irx1- ein Vormustergen essentiell für die murine Gastrulation / Functional analysis of the Irx1 gene / Irx1 - a prepattern gene essential during murine gastrulation Zülch, Armin Uwe 28 June 2001 (has links) No description available. 570 Biowissenschaften, Biologie Iroquois Irx Mausgastrulation knock out-Technologie Maus Vormustergene Iroquois Irx murine gastrulation knock out mouse prepattern gene 42.23 WK 000: Entwicklungsbiologie
80	The generation of a candidate axial precursor in three dimensional aggregates of mouse embryonic stem cells Baillie-Johnson, Peter January 2017 (has links) Textbook accounts of vertebrate embryonic development have been based largely upon experiments on amphibian embryos, which have shown that the tissues of the trunk and tail are organised from distinct precursors that existed during gastrulation. In the mouse and chick, however, retrospective clonal analyses and transplantation experiments have demonstrated that the amniote body instead arises progressively from a population of axial precursors that are common to both the neural and mesodermal tissues of the trunk and tail. For this reason, they are known as neuro-mesodermal progenitors (NMps). Detailed studies of NMps have been precluded by their lack of a unique gene expression profile and the technical difficulties associated with isolating them from the embryo. Mouse embryonic stem cells (ESCs) provide the possibility of instead deriving them in vitro. ESCs have been used to model developmental processes, partly through large cellular aggregates known as embryoid bodies. These structures do not, however, resemble the axial organisation of the embryo and they develop in a disordered manner. This thesis presents a novel culture system of small, three-dimensional aggregates of ESCs (gastruloids) that can recreate the events of early post-implantation development, including axial elongation. Gastruloids are the first ESC-based model for axial elongation morphogenesis; this body of work characterises their development and identifies a candidate population of NMps within their elongating tissues. Additionally, this work establishes a xenotransplantation assay for testing the functional properties of in vitro-derived NMp populations in the chicken embryo and applies it to NMps from gastruloid cultures. The results of this assay show that gastruloids are a credible source of NMps in vitro and therefore offer a new experimental means to interrogate their properties. The use of gastruloids to recreate embryonic development has implications for basic research as a synthetic system and for the therapeutic derivation of other embryonic progenitors through bioengineering. 612.6

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