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Browsing by Subject "Cilien"

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    Determination of Laterality in the Rabbit Embryo: Studies on Ciliation and Asymmetric Signal Transfer
    (2007) Feistel, Kerstin; Blum, Martin
    The midline of the vertebrate embryo plays a pivotal role in the regulation of left-right (LR) asymmetry. In mammals recent interest has focused on a structure situated at the caudal part of the notochord, the posterior notochord (PNC), which is homologous to Kupffer?s vesicle (KV) in fish and the gastrocoel roof plate (GRP) in frog. Despite highly diverging embryonic architecture, the PNC/KV/GRP is the site where motile monocilia set up a directional fluid flow, an event indispensable for the generation of LR asymmetry. Signals created at the PNC/KV/GRP need to be transferred to the periphery of the embryo, where they initiate the left-specifying program in the left lateral plate mesoderm (LPM). In this study morphogenesis and ciliogenesis of the notochordal plate as well as the signaling processes between midline and LPM were studied in the rabbit embryo. Rabbit development progresses through a flat blastodisc phase and represents the typical mode of mammalian embryogenesis. Transcription of ciliary marker genes, the first sign of beginning ciliogenesis, initiated in Hensen?s node and persisted in the nascent notochord. Cilia emerged on cells leaving Hensen?s node anteriorly to form the notochordal plate. Cilia lengthened to about 5µm and polarized from an initially central position to the posterior pole of cells. Electron microscopic analysis revealed 9+0 and 9+2 cilia and a novel 9+4 axoneme intermingled in a salt-and-pepper-like fashion. These data showed that the ciliogenic gene program essential for laterality determination is conserved at the midline of the rabbit embryo. The present study also provided evidence that initiation as well as repression of the Nodal cascade crucially depended on communication between midline and lateral plate (LP). Separation of LP tissue from the midline before, during and after the 2 somite stage demonstrated that signals from the PNC induced and maintained the competence of LPM to express Nodal. Signals from the midline were necessary after the 2 somite stage to maintain a right-sided identity, i.e. absence of Nodal expression. Gap-junction-dependent intercellular communication (GJC) was shown to play a central role in this process. Previously, GJC had been involved in LR axis determination in cleavage stage frog embryos and early blastodisc stages in chick. This study for the first time demonstrates the role of GJC in mammalian embryos. GJs regulate the signaling between midline and periphery: permeable gap junctions were required specifically at the 2 somite stage to repress Nodal induction in the right LPM, whereas closed GJs were a prerequisite for Nodal signaling on the left side. Establishment of the right-sided fate depended on FGF8, the signaling of which was regulated by the opening status of GJs. A 3-step model is proposed for symmetry breakage and induction of the LR signaling cascade in vertebrates: (1) Nodal protein synthesized at the lateral edges of the PNC diffuses bilaterally and confers competence for the induction of the Nodal cascade to the LPM, (2) at the same time the left-specific cascade is actively repressed by action of the GJC/FGF8 module, and (3) following the onset of leftward flow at the PNC repression gets released specifically on the left side at the 2 somite stage, presumably by transient inhibition of GJC. This model not only is consistent with the presented data, but also with published work in other model organisms.
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    Die Rolle von hmmr während Neurulation und Hirnentwicklung im Afrikanischen Krallenfrosch Xenopus laevis
    (2016) Hagenlocher, Cathrin; Schweickert, Axel
    The cerebrospinal fluid (CSF) fills the entire ventricular system of the brain, the spinal cavity and the subarachnoid space. CSF mechanically buffers the brain, transports signaling molecules and eliminates waste products. It is produced by the choroid plexus (CP) and transported throughout the ventricular system via motile cilia. Excessive production, diminished transport or reduced absorption of CSF lead to hydrocephalus, a pathological dilatation of the brain ventricles. Mutations in humans and mice showed that dysfunctional and immotile cilia also induce hydrocephalus. The underlying mechanism through which disturbed ciliary motility leads to formation of hydrocephalus is not resolved. In the present thesis the model organism Xenopus laevis was used to analyze the occurrence of hydrocephalus upon on ciliary dysmotility. Biogenesis of motile cilia was described in the Xenopus laevis brain up to metamorphosis. Gene expression of foxj1, the superior regulator of the biogenesis of motile cilia, correlated with development of elongated monocilia and the switch to multiciliated ependymal cells. Cilia on foxj1-positive cells were motile and produced a directional flow of CSF. foxj1 loss-of-function led to impaired or absent motile cilia and resulted in hydrocephalus. The development of the hydrocephalic dilatation correlated with reduced velocity of the cilia-driven CSF-flow below 300 µm/s. In cilia of the airway epithelium regulation of ciliary beat frequency via HMMR has been described with HMMR loss-of-function resulting in reduced ciliary beat frequency. In line with these results, hmmr loss-of-function in Xenopus laevis resulted in reduced velocity of CSF-flow and hydrocephalus. This suggests that especially in the fourth ventricle CSF-flow velocities above 300 µm/s are necessary to maintain a homeostatic fluid pressure in the entire ventricular system. The loss-of-function of foxj1 as well as hmmr further led to severe malformations in the dorsal midline of the brain, especially of the CP and the subcommissural organ. These ciliated structures have already been connected to development of hydrocephalus. Brain defects after loss-of-function of hmmr reflected the human disorder of holoprosencephaly (HPE) which often results from mutations in the Shh-signaling pathway and leads to hydrocephalus. Interestingly after hmmr loss-of-function induced HPE was independent of the Shh-signaling pathway. Forebrain development was disturbed because hmmr was necessary for microtubule-mediated cell adhesion during the morphogenetic movements of neurulation. This study shows for the first time, that CSF in Xenopus laevis is transported via motile cilia and confirmes that dysfunction or absent motile cilia lead to congenital hydrocephalus. Furthermore a novel role for motile cilia during fore- and midbrain morphogenesis was demonstrated. Development of hydrocephalus together with forebrain defects in foxj1 and hmmr morphants implies that cilia-dependent hydrocephalus can result from malformed dorsal midline structures. This study thus provides a basis to establish Xenopus laevis as a model organism to study the development of hydrocephalus caused by primary cilia dyskinesia and by forebrain defects.