@phdthesis{Gan2011, author = {Gan, Qiang}, title = {Investigation on Distinct Roles of Smad Proteins in Mediating Bone Morphogenetic Proteins Signals}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-71127}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2011}, abstract = {Knochenmorphogenetische Proteine (engl. Bone morphogenetic Proteins, BMPs) sind eine Bestandteil von transforming growth factor-β (TGF-β)-Superfamilie und spielen wichtige Rollen in zahlreichen biologischen Ereignissen in der Entwicklung fast aller mehrzelligen Organismen. Fehlregulierte BMP-Signalweg ist die zugrunde liegenden Ursachen von zahlreichen erblichen und nicht erblichen Krankheiten wie Krebs. Die von BMP induziete breite Palette von biologischen Reaktionen konvergiert auf drei eng verwandten Smad Proteine. Sie vermitteln intrazellul{\"a}re Signale von BMP-Rezeptoren in den Zellkern. Die Spezifit{\"a}t des BMP-Signalwegs wurde intensiv auf der Ebene der Ligand-Rezeptor-Wechselwirkungen erforscht, aber, wie die verschiedenen Smad Proteine die durch BMPs hervorgerufen differenziellen Signale beitragen, bleibt unklar. In dieser Arbeit haben wir die BMP / Smad Signalweg in verschiedenen Aspektenuntersucht. Auf der Suche nach einem geeigneten Fluoreszenz-Reporter im Zebrafisch, verglichen wir verschiedene photo-schaltbaren Proteine und fand EosFP der beste Kandidat f{\"u}r diesen Modellorganismus im Bezug auf seine schnelle Reifung und Fluoreszenz-Intensit{\"a}t. Wir haben durch molekulare Modifizierung geeignete Vektoren erstellt, die Tol2-Transposon basieren trangenesis im Zebrafisch zu erm{\"o}glichen. Damit wurden schließlich transgenzebrafisch-Linien erzeugt. Wir kombinierten Fluoreszenz-Protein-Tagging mit hochaufl{\"o}sender Mikroskopie und untersuchten die Dynamik der Smad-Proteine in Modellsystem Zebrafisch. Es wurde beobachteten, dass Smad5 Kern-Translokation erf{\"a}hrt, als BMP Signalgeber bei Zebrafisch Gastrulation. Wir erkundeten die Beteiligung der Smad Proteine w{\"a}hrend der Myogenese-zu-Osteogenese Umwandlung von C2C12 Zelllinie, die durch BMP4 induziert wurde. Mit siRNA versuchten wir die endogene Smad Proteine niederzuschlagen, wobei die Auswirkungen auf diesen gekoppelten noch unterschiedlichen Verfahren durch quantitative real-time PCR und Terminal-Marker F{\"a}rbung ausgewertet. Wir spekulieren, dass verschiedene Smad-Komplex St{\"o}chiometrie f{\"u}r unterschiedliche durch BMPs hervorgerufe zellul{\"a}re Signale verantwortlich sein k{\"o}nnte.}, subject = {Knochen-Morphogenese-Proteine}, language = {en} } @phdthesis{Schaefer2005, author = {Sch{\"a}fer, Matthias}, title = {Molecular mechanisms of floor plate formation and neural patterning in zebrafish}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-15789}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2005}, abstract = {The vertebrate spinal cord is composed of billions of neurons and glia cells, which are formed in a highly coordinated manner during early neurogenesis. Specification of these cells at distinct positions along the dorsoventral (DV) axis of the developing spinal cord is controlled by a ventrally located signaling center, the medial floor plate (MFP). Currently, the origin and time frame of specification of this important organizer are not clear. During my PhD thesis, I have analyzed the function of the novel secreted growth factor Midkine-a (Mdka) in zebrafish. In higher vertebrates, mdk and the related factor pleiotrophin (ptn) are widely expressed during embryogenesis and are implicated in a variety of processes. The in-vivo function of both factors, however, is unclear, as knock-out mice show no embryonic phenotype. We have isolated two mdk co-orthologs, mdka and mdkb, and one single ptn gene in zebrafish. Molecular phylogenetic analyses have shown that these genes evolved after two large gene block duplications. In contrast to higher vertebrates, zebrafish mdk and ptn genes have undergone functional divergence, resulting in mostly non-redundant expression patterns and functions. I have shown by overexpression and knock-down analyses that Mdka is required for MFP formation during zebrafish neurulation. Unlike the previously known MFP inducing factors, mdka is not expressed within the embryonic shield or tailbud but is dynamically expressed in the paraxial mesoderm. I used epistatic and mutant analyses to show that Mdka acts independently from these factors. This indicates a novel mechanism of Mdka dependent MFP formation during zebrafish neurulation. To get insight into the signaling properties of zebrafish Mdka, the function of both Mdk proteins and the candidate receptor Anaplastic lymphoma kinase (Alk) have been compared. Knock-down of mdka and mdkb resulted in the same reduction of iridophores as in mutants deficient for Alk. This indicates that Alk could be a putative receptor of Mdks during zebrafish embryogenesis. In most vertebrate species a lateral floor plate (LFP) domain adjacent to the MFP has been defined. In higher vertebrates it has been shown that the LFP is located within the p3 domain, which forms V3 interneurons. It is unclear, how different cell types in this domain are organized during early embryogenesis. I have analyzed a novel homeobox gene in zebrafish, nkx2.2b, which is exclusively expressed in the LFP. Overexpression, mutant and inhibitor analyses showed that nkx2.2b is activated by Sonic hedgehog (Shh), but repressed by retinoids and the motoneuron-inducing factor Islet-1 (Isl1). I could show that in zebrafish LFP and p3 neuronal cells are located at the same level along the DV axis, but alternate along the anteroposterior (AP) axis. Moreover, these two different cell populations require different levels of HH signaling and nkx2.2 activities. This provides new insights into the structure of the vertebrate spinal cord and suggests a novel mechanism of neural patterning.}, subject = {Zebrab{\"a}rbling}, language = {en} }