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Defining the Regional and Lineage Contribution of Early Mesp1 Cardiovascular Progenitors During Mammalian Heart DevelopmentChabab, Samira 17 May 2016 (has links)
The heart arises from two sources of mesoderm progenitors, the first (FHF) and the second heart field (SHF) progenitors. Mesp1 has been proposed to mark the most primitive multipotent cardiac progenitors (MCPs) common for both heart fields. However, it remains unclear whether at the single cell level, Mesp1 progenitors represent a common progenitor for the FHF and SHF. Using mosaic tracing and inducible clonal analysis with a multicolor reporter strategy, we investigated the contribution of Mesp1 cardiovascular progenitors in a temporally controlled manner during the early gastrulation. Our data indicated that the myocardium derives from ~250 Mesp1 expressing cardiac progenitors born during gastrulation. Temporal analysis of clonally labeled Mesp1 cells revealed the existence of temporally distinct populations of Mesp1 progenitors that are restricted to either the FHF or the SHF. FHF progenitors were unipotent, while SHF progenitors, were either uni- or bipotent. Microarray and single cell RT-PCR analysis of Mesp1 progenitors revealed the existence of molecularly distinct populations of Mesp1 progenitors, consistent with their lineage and regional contribution. Moreover biophysical analysis of clonal data revealed that, despite arising at different time points and contributing to different heart regions, the temporally distinct cardiac progenitors present very similar clonal dynamics. Altogether, these results provide insights into the number of cardiac progenitors and their mode of growth. Moreover they provide evidence that heart development arises from distinct populations of unipotent and bipotent cardiac progenitors expressing Mesp1 independently at different time points during gastrulation. Our data reveal that the regional segregation and lineage restriction of cardiac progenitors occurs very early during embryonic development. / Doctorat en Sciences biomédicales et pharmaceutiques (Médecine) / info:eu-repo/semantics/nonPublished
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DISHEVELLED-ASSOCIATED ACTIVATOR OF MORPHOGENESIS 1 (DAAM1) IS REQUIRED FOR HEART MORPHOGENESISLi, Deqiang 02 February 2010 (has links)
Indiana University-Purdue University Indianapolis (IUPUI) / Dishevelled-associated activator of morphogenesis 1 (Daam1), a member of the formin protein family, has been implicated in the non-canonical Wnt mediated Planar Cell Polarity (PCP) signaling pathway. Although the studies in Drosophila Daam1 and Xenopus Daam1 generated inconsistent conclusions regarding the function of Daam1, the biological function of mammalian Daam1 was not evaluated. In this study, we used a mouse promoter trap technology to create Daam1 deficient mice to analyze the role of Daam1 in embryonic development and organogenesis. Daam1 is highly expressed in the developing heart. The majority of Daam1 mutant mice died between embryonic day 14.5 and birth, exhibiting a variety of heart defects, which include ventricular noncompaction, ventricular septal defects, and double outlet right ventricle. About 10% mutant mice survive to adulthood, and these survivors do not show significantly compromised heart function based on echocardiographic analyses. However, all of these mutant survivors have ventricular noncompaction with a range of severities. A conditional rescue experiment using a cardiac specific Cre mouse line, Nkx2-5Cre, confirmed that the cardiac defects are the primary cause of death in Daam1 mutants. Both in vivo and ex vivo analyses revealed that Daam1 is essential for regulating non-sarcomeric filamentous actin assembly in cardiomyocytes, which likely contributes to cardiac morphogenesis and ventricular wall maturation. Biochemical studies further suggested that Daam1 is not a key signaling component in regulating the activation of small GTPases, such as RhoA, Rac1 and Cdc42. In conclusion, our studies demonstrated that Daam1 is essential for cardiac morphogenesis likely through its regulation of cytoskeletal architecture in the developing cardiomyocytes. / indefinitely
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Functional Analysis of the Role of Slit and its Receptors During D. melanogaster Heart MorphogenesisVassilieva, Katerina 12 1900 (has links)
Proper formation of the heart is a critical developmental event which requires strict
regulation of coordinated cardial cell adhesion, alignment, and migration. The simple, tube-like heart of the fruit fly, Drosophila melanogaster, has proven to be an attractive system in which to study the regulatory pathways which control cardiogenesis. This is mainly due to its strikingly similarity to the vertebrate heart during early embryogenesis. In addition, many genes identified in association with congenital heart disease in humans have homologues in Drosophila, suggesting that this model organism has great potential to contribute to cardiovascular research. The extracellular matrix protein encoded by slit is a ligand for the receptors Robo, and Robo2 (lea). Recently, a third receptor for Slit has been identified as the heparin sulfate proteoglycan Syndecan. The main objective of this thesis was to use time lapse confocal imaging in order to develop further understanding of the mechanisms which result in heart assembly defects in slit, robo, lea, and syndecan mutants. We also aimed to gain a better understanding of the role of Syndecan within the Slit-Robo pathway and elucidate its relative contribution to development of the mature heart. In mutants homozygous for slit, as well as mutants doubly heterozygous for robo and lea, cardial cell alignment, adhesion, and synchronized migration were disrupted. The heart phenotype of syndecan homozygous mutants was similar that of slit and robo, lea, however the migration speed of cells to the midline did not seem to be affected. Based on our findings, we hypothesize that Slit may have Syndecan-dependent and Syndecan-independent functions in the heart. / Thesis / Master of Science (MSc)
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Function of the alpha1B1 subunit of Na +, K + ATPase during zebrafish heart developmentCibrian-Uhalte, Elena 07 August 2008 (has links)
Die Zebrafischmutation heart and mind (had), welche die alpha1B1-Untereinheit der Na+,K+ ATPase betrifft, verzögert die Streckung des Herzschlauches und führt zu weiteren Entwicklungsanomalien, die an andere Zellpolaritätsmutanten wie nagie oko (nok) und heart and soul (has) erinnern. In dieser Arbeit habe ich die Funktion und Regulation von Had/Na+,K+ ATPase während der Herzmorphogenese des Zebrafisches und seine möglichen Interaktionen mit Has/Prkci und Nok/Mpp5 untersucht. In konnte nachweisen, dass genetische Interaktionen zwischen had und nok in der Aufrechterhaltung von Zonula-Occludens-1-(ZO-1)-positiven Adhäsionsbändern Adhäsionsbändern in myokardialen Zellen während der Herzentwicklung nachweisen. Meine Ergebnisse deuten darauf hin, dass die Interaktion zwischen Nok/Mpp5 und Had/Na+,K+ ATPase zur Aufrechterhaltung der myokardialen ZO-1-Adhäsionsbändern die Funktion der Na-Pumpe erfordert und dass die korrekte Ionengradienten zur Aufrechterhaltung der myokardialen Integrität beiträgt. Meine Ergebnisse zeigen eine Phosphorylierung des N-terminalen Endes von Had/ Na+,K+ ATPase durch PKCs. PKCs wurden bereits mit der Regulation der Na-Pumpen-Funktion durch Phosphorylierung von N-terminalen Resten in Verbindung gebracht. Meine Ergebnisse legen die Möglichkeit nahe, dass dieser Mechanismus im Zebrafisch konserviert ist. Die Analyse der subzelluläre Lokalisation einer Phosphorylierungs-defizienten Form von Had/Na+,K+ ATPase legt nahe, dass während Herzschlauch-elongation die Had/Na+,K+ ATPase-Aktivität an der Zellmembran durch die Phosphorylierung an einer amino-terminalen Amino-säure reguliert wird. Frühere Studien legen nahe, dass die Herzmorphogenese durch direkte Phosphorylierung von Has/Prkci-Zielen gesteuert wird. Die Identifikation von Has/Prkci-Phosphorylierungs-Zielen könnte dazu beitragen, Herzmorphogenese besser zu verstehen. Aus diesem Grund wurde ein chemisch-genetischer Ansatz entwickelt, um direkte Phosphorylierungs-Ziele von Has/Prkci zu identifizieren. / The zebrafish heart and mind (had) mutation which disrupts the alpha1B1 subunit of Na+,K+ ATPase causes heart tube elongation defects and other developmental abnormalities that are reminiscent of several epithelial cell polarity mutants including nagie oko (nok) and heart and soul (has). In this work, I investigated the function and regulatory mechanisms of Had/Na+,K+ ATPase during zebrafish cardiac morphogenesis, as well as its´ possible interactions with Has/Prkci and Nok/Mpp5. In this study, I demonstrate genetic interactions between had and nok in maintaining Zonula occludens-1 (ZO-1) positive junction belts within myocardial cells during heart development. My results strongly suggest that the interaction between Nok/Mpp5 and Had/Na+,K+ ATPase in the maintenance of myocardial ZO-1 junction belts requires the Na pump function and that the correct ionic balance contributes to the maintenance of myocardial integrity. My results show phosphorylation of the N-terminal intracellular tail of Had/Na+,K+ ATPase by PKCs. PKCs have previously been implicated in the regulation of the Na pump function via phosphorylation of N-terminal residues. Therefore, my results raise the possibility that this mechanism is conserved in the zebrafish embryo. The analysis of the subcellular distribution of a phosphorylation-deficient form of Had/Na+,K+ ATPase suggests that, during heart tube elongation, Had/Na+,K+ ATPase activity is regulated at the membrane via phosphorylation at an amino-terminal site. Previous studies suggest that heart morphogenesis is driven via direct phosphorylation of Has/Prkci targets. Therefore, identification of Has/Prkci phosphorylation targets would contribute to better understand cardiac morphogenesis. For this purpose, a chemical genetic approach was designed to identify Has/Prcki direct phosphorylation targets.
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Desarrollo de las válvulas semilunares en el embrión de pollo. Papel de los fáctortes hemodinámicosColvée Benlloch, Elvira 29 July 1982 (has links)
No description available.
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