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Improving Therapies of RhabdomyosarcomaRidzewski, Rosalie 07 December 2015 (has links)
No description available.
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In Vitro Differentiation of Muscle Side Population Cells from Dystrophic Muscle Reveals Absence of Myogenesis and Implications for Hedgehog SignalingPenton, Christopher January 2013 (has links)
No description available.
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THE ROLES OF HEDGEHOG AND AP-2 SIGNALING IN THE REGULATION OF LENS DEVELOPMENTKerr, Christine L. 04 1900 (has links)
<p>Lens development is an intricate process governed by growth factor signaling and a hierarchy of transcription factors that regulate important processes required for normal lens development.</p> <p>Midline hedgehog (Hh) signaling has been implicated in lens defects including cyclopia and lens degeneration in rodents and fish. A lens specific model of hedgehog signaling has not been examined, and it was unknown whether the lens is able to respond to Hh signals. To investigate this question, and to determine any consequences of abnormal Hh signaling on lens development, a mouse model of constitutively active smoothened in the surface ectoderm and derivatives, (including the lens), was created. These mutants exhibited ectopic expression of FoxE3 by E12.5, and ectopic Pax6 expression by E15.5, along with deregulation of the lens cell cycle and lens degeneration.</p> <p>Similar to the Hh signaling pathway, normal expression of the transcription factor Activating Protein-2 (AP-2, <em>tcfap2</em>), in the lens, was shown to be essential for the maintenance of an epithelial cell phenotype, and the regulation of the lens cell cycle. AP-2α has been shown to be important at the placode stage of development for correct separation of the lens vesicle away from the overlying surface ectoderm. Defects resulting from the loss of AP-2α at this stage do not manifest until E12.5, at time at which AP-2β expression is lost in the lens, suggesting possible redundancy between the two AP-2 family members in early lens development.</p> <p>To investigate this possible redundancy, <em>Tcfap2a </em>and <em>Tcfap2b</em> were conditionally deleted from the lens at E9.5 (AP-2α/β DKOs). These family members were shown to play redundant roles during early lens development, with the double mutants exhibiting more severe defects than those seen in the AP-2α single knockout model A more nasally positioned lens stalk and a rotated lens were observed. Severe corneal defects and deregulation of the lens cell cycle were also evident.</p> <p>Roles for AP-2α in later lens development were unknown. To examine whether or not this transcription factor continues to play a role in lens epithelial cell maintenance subsequent to lens vesicle separation, a mouse model with <em>Tcfap2a</em> conditionally deleted from the lens during these later stages of development was created (MRL10-AP-2α). These mutants displayed a disorganized and multilayered lens epithelial cell layer with elongated epithelial cells that abnormally expressed fiber cell specific β/γ crystallins. These mutants also exhibited defects in cell adhesion between the epithelium and fiber cells, as well as between the epithelium and capsule, and exhibited fiber cell defects including vacuoles.</p> <p>Together, the work presented in this thesis outline previously unknown roles for Hh and AP-2 signaling in lens development. Both Hh and AP-2 are required for the maintenance of a normal lens epithelial cell phenotype and regulation of the cell cycle. This thesis also illustrates the requirement (and redundant roles) for AP-2α and AP-2β at the lens placode stage of development.</p> / Doctor of Philosophy (Medical Science)
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FLUOXETINE: EXAMINING THE SELECTIVE SEROTONIN RE-UPTAKE INHIBITOR’S EFFECTS ON SEROTONIN AND HEDGEHOG SIGNALING IN THE PANCREATIC BETA CELLAyyash, Ahmed January 2018 (has links)
Major depressive disorder (MDD) is one of the most common psychiatric illnesses worldwide, with pharmacotherapy as a first-line option for the management of this illness. The National Center for Health Statistics found that the use of antidepressants has increased by more than 4 fold in the last 20 years. While SSRI’s act centrally to treat MDD, their peripheral effects are often overlooked. Interestingly, components of the serotonergic system including the serotonin transporter (SERT), serotonin receptors, and enzymes important for serotonin synthesis (tryptophan hydroxylase 1 and 2; Tph1 and Tph2) are affected by SSRI treatment both centrally and peripherally. This disruption of serotonin signaling in the pancreas is of particular interest as there is a considerable link between the serotonin and hedgehog signaling pathways, both of which are important for pancreatic beta cell function. I hypothesize that pancreatic beta cell exposure to the SSRI fluoxetine in vitro will lead to altered hedgehog signaling ultimately resulting in a disruption in insulin secretion. / Thesis / Master of Science in Medical Sciences (MSMS)
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Die Bedeutung der Hedgehog- Signalkaskade in der Tumorgenese von spinalen und kraniellen Chordomen / The role of hedgehog signaling pathway in skull base and sacrum chordomasKlemer-Harcej, Amanda Angelika 17 July 2017 (has links)
No description available.
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The Role of Sox4 in Regulating Choroid Fissure Closure and Retinal NeurogenesisWen, Wen 01 January 2016 (has links)
The development of the vertebrate eye is tightly controlled by precise genetic regulations. From a single ocular primordium to bilateral eyes with complex structures and cell types, it requires intensive proliferation and migration for cells in both the ectoderm and mesoderm to accomplish ocular morphogenesis, and during this process cell differentiation and interaction takes place to establish the complex composition of ocular cell types and cellular connections. Genetic defects can lead to severe abnormalities in eye morphogenesis and cell differentiation during ocular development. A tremendous amount of work has been done to identify both intrinsic and extrinsic factors that regulate ocular development. However, much more work is needed to fully understand this complex process.
Sox4 is known as a transcription activator that regulates cell survival and differentiation in multiple embryonic tissues during development. Evidence of its requirement during ocular development has recently emerged, but the mechanism by which Sox4 regulates ocular development is far from elucidated. Chapter 1 of this dissertation provides an overview of different stages in embryonic eye development and known genetic interactions during each stage. It also reviews recent knowledge about SoxC proteins and their roles in ocular development. Chapter 2 presents data characterizing the expression profile of the zebrafish sox4 co-orthologs, sox4a and sox4b, in the developing eye. Additionally, it presents data from morpholino-mediated sox4 knockdown in zebrafish, which indicate that Sox4 deficiency leads to defects in choroid fissure closure through elevation in the Hedgehog (Hh) signaling pathway. Sox4 knockdown causes upregulation of the Hh ligand indian hedgehog b (ihhb), which alters the proximal-distal boundary of the optic vesicle and inhibits choroid fissure closure. Chapter 3 presents data reporting the generation of sox4 mutant zebrafish lines using the CRISPR/Cas9 genome editing system. Characterization of one sox4a maternal zygotic (MZ) mutant line confirms Sox4’s role in negative regulation of Hh signaling and reveals new evidence that maternal and zygotic sox4 are both critical for ocular development. Chapter 4 presents data demonstrating that sox4 is required for rod photoreceptor neurogenesis. Rod photoreceptor terminal differentiation is delayed in both sox4 morphants and sox4 CRISPR mutants, while rod progenitor and precursor cells are properly specified. In Chapter 5, the roles of Sox4 in regulating ocular development are summarized based on the results, and implications of the results are discussed to expand our understanding of the genetic regulation of ocular morphogenesis and retinal neurogenesis.
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ROLE OF SOX11 DURING VERTEBRATE OCULAR MORPHOGENESIS AND RETINAL NEUROGENESISPillai, Lakshmi Shashidharan 01 January 2015 (has links)
Microphthalmia, anophthalmia, and coloboma (MAC) are distinct abnormalities demonstrating a continuum of developmental eye defects that contribute to 15-20% of blindness and severe vision deficiencies in children worldwide. The genetic etiology of MAC is large, complex and encompasses the whole developmental biology of the eye. Understanding how the eye develops will aid in identifying genes and developmental pathways involved in MAC. Although investigation of the genetic architecture of congenital anomalies is growing exponentially, much work remains to be accomplished to understand the complex, genetically heterogeneous congenital anomalies, which significantly impact childhood vision.
With an interest in elucidating the mechanisms that are involved in eye morphogenesis, I have characterized a SRY-Box transcription factor, Sox11, during zebrafish ocular development. The SRY (sex determining region Y)-box 11 (sox11) gene, codes for a transcription factor which functions as a regulator of cell fate, survival, and differentiation in the embryonic and adult nervous system. By titrating the levels of sox11 gene function in developing zebrafish embryos I have investigated the role of Sox11 during ocular morphogenesis and retinal neurogenesis. Chapter 1 of this dissertation provides a review of vertebrate eye development with a focus on emerging roles of SoxC proteins during vertebrate ocular morphogenesis. Chapter 2 presents data demonstrating that knockdown of both paralogs of sox11 in zebrafish results in microphthalmia, coloboma, as well as a specific deficit in mature rod photoreceptors. Additionally, we demonstrate for the first time that Sox11 regulates early ocular and photoreceptor development in part by maintaining proper levels of Hedgehog (Hh) signaling. Deficiency of Sox11 results in elevated Sonic Hedgehog a (Shha) transcript levels, which in turn leads to improper patterning of the optic vesicle into the proxio-distal territories. Furthermore, the data indicate that alterations in SOX11 gene dosage or mutation within the SOX11 coding region are potentially disease causing and contribute to human ocular defects like MAC and rod dysfunction. Chapter 3 presents data indicating that sox11 gene function is required during the critical period of neurulation (4-10 hours post fertilization) to guide choroid fissure closure and proper ocular morphogenesis to occur in the developing zebrafish. Chapter 4 is a technical report on the progress towards generating stable sox11a/b knockout zebrafish lines using the CRISPR/Cas9 genome editing approach. Transient F0 injected embryos and F0 adults carry mutations in the sox11a/b target site in addition to displaying ocular abnormalities similar to those previously reported in sox11 morphants. F1 juveniles are ready to be screened for establishment of mutagenesis efficiency and germ line transmission. Finally, in Chapter 5 I discuss how the results of each chapter demonstrate the functional requirement of Sox11 for ocular development. Furthermore, I discuss the implications of this work in the field of developmental biology and how the current data will shape future investigations. My dissertation incorporates human genetics, biochemical analyses, and zebrafish reverse genetic analyses, and will help in better understanding the exact role of Sox11 during eye development at the cellular and molecular level. Moreover, by identifying Sox11 targets belonging to the Hh pathway, as well as novel targets of Sox11 regulation, these studies may also contribute to our understanding of the function of Sox11in development and disease pathogenesis.
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Role of RAS signaling in Hedgehog-associated embryonal rhabdomyosarcomaBauer, Julia 18 December 2018 (has links)
No description available.
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Die pharmakologische Beeinflussung des Hedgehog Signaltransduktionsweges in Kopf-Hals-Tumoren ex vivoStöhr, Matthäus 20 January 2015 (has links)
Der Hedgehog Signaltransduktionsweg (HhP) ist in der Embryologie und für die Tumor-entstehung bedeutsam und kann durch den spezifischen Antagonisten Cyclopamin (Cyc) inhibiert werden. Simvastatin (Sim) kann die für den HhP essentielle Cholesterolsynthese blockieren. Die therapeutische Unterdrückung des HhP in Kopf-Hals-Plattenepithel-karzinomen (HNSCC) zu untersuchen erschien nach verschiedenen Literaturhinweisen lohnend. In den Experimenten, deren Ergebnisse bereits in Artikeln publiziert wurden, konnten antineoplastische Effekte von Cyc bzw. Sim allein und in Kombination mit den Leitlinientherapeutika Cisplatin (Cis) oder Docetaxel (DTX) an der epithelialen Zelllinie KB, den Kopf-Hals-Zelllinien FaDu und HN-5, sowie an primären HNSCC ex vivo nachgewiesen werden. Biopsien von 49 HNSCC wurden im FLAVINO-Assay mit Cyc bzw. Sim in steigenden Konzentrationen allein und kombiniert mit Cis oder DTX untersucht. In die Auswertung konnten gemäß den Einschlusskriterien (histopathologisch bestätigtes HNSCC und suffiziente Koloniebildung im FLAVINO-Assay) 18 HNSCC einbezogen werden. Bei den Voruntersuchungen führten sowohl Cyc als auch Sim zu einer signifikanten Zeit- und Dosis-abhängigen Reduktion der Lebensfähigkeit von KB, FaDu und HN-5. Ebenso unterdrückten sowohl Cyc als auch Sim die Koloniebildung epithelialer Zellen im FLAVINO-Assay hochsignifikant. Auch tolerierbare Cis- und DTX-Konzentrationen zeigten eine signifikante Wachstumshemmung. In der Analyse des Interaktionsmodus wurde in den untersuchten Kombinationen (Sim+Cis, Sim+DTX, Cyc+Cis und Cyc+DTX) in allen Fällen Additivität als prädominanter Interaktionstyp ermittelt. Die Ergebnisse dieser Arbeit weisen den HhP als potentielles Target in HNSCC aus. Potentere und human besser verträgliche HhP-Blocker sollten unsere Ergebnisse bestätigen und in klinischen Studien getestet werden. Auch die Wirksamkeit von Sim auf HNSCC sollte in prospektiven klinischen Studien weiter analysiert und bestätigt werden. Möglicherweise vermag Sim bzw. die HhP-Blockade zukünftig einen Beitrag zur Therapie von HNSCC im Rahmen multimodaler Therapiekonzepte zu leisten.
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Hedgehog signaling regulates mechanical tension along the anteroposterior compartment boundary in the developing Drosophila wingRudolf, Katrin 04 August 2014 (has links)
The interplay between biochemical signals and mechanical processes during animal development is key for the formation of tissues and organs with distinct shapes and functions. An important step during the formation of many tissues is the formation of compartment boundaries which separate cells of different fates and functions. Compartment boundaries are lineage restrictions that are characterized by a straight morphology. Biochemical signaling across compartment boundaries induce the expression of morphogens in the cells along the boundaries. These morphogens then act at long-range to direct growth and patterning of the whole tissue. Compartment boundaries stabilize the position of morphogens and thereby contribute to proper tissue development.
The straight morphology of compartment boundaries is challenged by cell rearrangements caused by cell division and tissue reshaping. Physical mechanisms are therefore required to maintain the straight morphology of compartment boundaries. The anteroposterior (A/P) compartment boundary in the developing Drosophila melanogaster wing is established by biochemical signals. Furthermore, mechanical processes are required to maintain the straight shape of the A/P boundary. Recent studies show that mechanical tension mediated by actomyosin motor proteins is increased along the A/P boundary.
However, it was not understood how biochemical signals interact with mechanical processes to maintain the A/P boundary. Here I provide the first evidence that Hedgehog signaling regulates mechanical tension along the A/P boundary. I was able to show that differences in Hedgehog (Hh) signal transduction activity between the anterior and posterior compartments are necessary and sufficient to maintain the straight shape of the A/P boundary, which is crucial for patterning and growth of the adult wing. Moreover, differences in Hh signal transduction activity are necessary and sufficient for the increase in mechanical tension along the A/P boundary.
In addition, differences in Hh signal transduction activity are sufficient to generate smooth borders and to increase mechanical tension along ectopic interfaces. Furthermore, the differential expression of the transmembrane protein Capricious is sufficient to increase mechanical tension along ectopic interfaces. It was previously suggested that mechanical tension is generated by an actomyosin-cable through which the increase in mechanical tension is transmitted between the junctions along the A/P boundary. Here I show that mechanical tension is generated locally at each cell bond and not transmitted between junctions by an actomyosin cable. My results provide new insights for our understanding of the interplay between biochemical signals and mechanical processes during animal development.
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