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Browsing by Subject "Myosin1d"

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    Funktionelle Analyse der Gene Brachyury, Goosecoid und Myosin1d für die frühe Musterbildung und Etablierung der Körperachsen während der Embryogenese des Krallenfroschs Xenopus laevis
    (2019) Kurz, Sabrina; Blum, Martin
    During a fundamental phase of vertebrate embryonic development, gastrulation, the reorganization of the future body plan, is determined. This process controls the embryonic patterning of the antero-posterior (AP) and dorso-ventral (DV) axes, as well as the internal left-right (LR) axis. The establishment of the body axes is initially controlled by the dorsally localized Spemann organizer (SO), whereby the determination of the LR axis takes place the latest. The formation of laterality during subsequent neurulation is executed by a highly conserved mechanism of symmetry breakage within fishes, amphibians and mammals. An extracellular, monocilia-driven fluid-flow („Flow") eventually defines the laterality of the embryo, by left-asymmetric gene expression of the morphogen Nodal. Responsible for the Flow is a ciliated epithelium in the postero-dorsal region of the embryo, which undergoes morphological development and correct positioning during gastrulation and is termed GRP („gastrocoel roof plate") in the frog. Ultimately, this conserved tissue describes the left-right organizer (LRO) and guarantees proper organ situs. The origin and function of the LRO can be traced back to an epithelial organized cell structure on the dorsal surface of the gastrula, characterized by the expression of the canonical Wnt target gene and cilia marker foxj1. Following the specification of this Superficial Mesoderm (SM), the future cells of the LRO invaginate in a directed fashion during gastrulation. The patterns of cellular movement require a restructuring of the actin-cytoskeleton. These migrations, executing the future body plan, are ensured by the PCP- („planar cell polarity”) signaling pathway. This non-canonical Wnt pathway guarantees polarized alignment and migration of cells along the body axes, namely convergent extension (CE). As an organizer gene, the expression of Goosecoid (Gsc) characterizes SO and its’ properties. Contrary to the assumption that a Gsc loss of function thus inhibits gastrulation, no visible impairment was detected in the Knock-Out mouse and Knock-Down in Xenopus. Gain-of-function in the frog, which analyzed the role of Gsc during gastrulation finally demonstrated the homeobox-gene exerting a function in regulating cell movements. Overexpression resulted in impaired CE of dorsal tissue due to defective localization of nuclear proteins of the PCP signaling pathway. Gsc-induced malformations could be compensated by co-injections of associated components. In conclusion, a new function as an inhibitor of PCP-dependent CE during gastrulation was suggested. The morphogenetic movements of CE are responsible for the AP-elongation and LRO-positioning. Both, mechanical forces and cilia-based Flow functionally interact for that matter. In the invertebrate Drosophila, where neither Nodal nor cilia are expressed, organ asymmetry is ensured by internal chirality conducted via motor proteins, such as myosin1d, in a PCP-dependent manner. Similarly, in vertebrates such as Xenopus, myo1d mediates interactions of the actin cytoskeleton asymmetrically, that guarantee laterality of the organ system. The functional preservation of the non-canonical Wnt pathway could be demonstrated by co-injections of PCP core proteins, being able to restore disturbed LRO morphology. The obtained data clearly demonstrated the evolutionary, interspecific, regulation of axis asymmetry by myo1d. Since the strict spatio-temporal regulation of cell movements is fundamental for patterning, CE is propagated by another transcription factor: Brachyury (Tbxt in Xenopus). Its expression induces and controls differentiation of mesodermal cell populations, such as the notochordal cells of the dorsal midline, hence LRO. The necessity specifying progenitor cells in the SM could also be highlighted, showing to be mediated non-cell autonomously to guarantee the induction of foxj1. Additionally, the determination of both tissues is exerted by functional interactions of Tbxt with either PCP-, as well as ß-catenin-dependent Wnt signaling pathway. Loss of Brachyury affects laterality in mutants and morphants. The species-spanning Brachyury-FGF „feedback-loop" for the induction of Nodal and Foxj1 could already act in the SM and showed that function as well as the process of LR development, as suggested between Fgf8 and Brachyury, to be functionally conserved. In Xenopus, signal transduction for SM and foxj1 induction was extended by the function of the Wnt receptor frizzled-8, the ligand and Tbxt target gene wnt11b, and the ventrally acting wnt8a in Whole-Mount embryos and explant co-cultures.