BACKGROUND: Loss of function mutations in the centrosomal protein TALPID3 (KIAA0586) cause a failure of primary cilia formation in animal models and are associated with defective Hedgehog signalling. It is unclear, however, if TALPID3 is required only for primary cilia formation or if it is essential for all ciliogenesis, including that of motile cilia in multiciliate cells. RESULTS: FOXJ1, a key regulator of multiciliate cell fate, is expressed in the dorsal neuroectoderm of the chicken forebrain and hindbrain at stage 20HH, in areas that will give rise to choroid plexuses in both wt and talpid(3) embryos. Wt ependymal cells of the prosencephalic choroid plexuses subsequently transition from exhibiting single short cilia to multiple long motile cilia at 29HH (E8). Primary cilia and long motile cilia were only rarely observed on talpid(3) ependymal cells. Electron microscopy determined that talpid(3) ependymal cells do develop multiple centrosomes in accordance with FOXJ1 expression, but these fail to migrate to the apical surface of ependymal cells although axoneme formation was sometimes observed. CONCLUSIONS: TALPID3, which normally localises to the proximal centrosome, is essential for centrosomal migration prior to ciliogenesis but is not directly required for de novo centriologenesis, multiciliated fate, or axoneme formation.
BACKGROUND: Loss of function mutations in the centrosomal protein TALPID3 (KIAA0586) cause a failure of primary cilia formation in animal models and are associated with defective Hedgehog signalling. It is unclear, however, if TALPID3 is required only for primary cilia formation or if it is essential for all ciliogenesis, including that of motile cilia in multiciliate cells. RESULTS:FOXJ1, a key regulator of multiciliate cell fate, is expressed in the dorsal neuroectoderm of the chicken forebrain and hindbrain at stage 20HH, in areas that will give rise to choroid plexuses in both wt and talpid(3) embryos. Wt ependymal cells of the prosencephalic choroid plexuses subsequently transition from exhibiting single short cilia to multiple long motile cilia at 29HH (E8). Primary cilia and long motile cilia were only rarely observed on talpid(3) ependymal cells. Electron microscopy determined that talpid(3) ependymal cells do develop multiple centrosomes in accordance with FOXJ1 expression, but these fail to migrate to the apical surface of ependymal cells although axoneme formation was sometimes observed. CONCLUSIONS:TALPID3, which normally localises to the proximal centrosome, is essential for centrosomal migration prior to ciliogenesis but is not directly required for de novo centriologenesis, multiciliated fate, or axoneme formation.
Authors: Ruxandra Bachmann-Gagescu; Ian G Phelps; Jennifer C Dempsey; Vivek A Sharma; Gisele E Ishak; Evan A Boyle; Meredith Wilson; Charles Marques Lourenço; Mutluay Arslan; Jay Shendure; Dan Doherty Journal: Hum Mutat Date: 2015-07-02 Impact factor: 4.878
Authors: May Christine V Malicdan; Thierry Vilboux; Joshi Stephen; Dino Maglic; Luhe Mian; Daniel Konzman; Jennifer Guo; Deniz Yildirimli; Joy Bryant; Roxanne Fischer; Wadih M Zein; Joseph Snow; Meghana Vemulapalli; James C Mullikin; Camilo Toro; Benjamin D Solomon; John E Niederhuber; William A Gahl; Meral Gunay-Aygun Journal: J Med Genet Date: 2015-09-18 Impact factor: 6.318
Authors: Elizabeth N Schock; Ching-Fang Chang; Ingrid A Youngworth; Megan G Davey; Mary E Delany; Samantha A Brugmann Journal: Dev Biol Date: 2015-10-24 Impact factor: 3.582
Authors: Louise A Stephen; Hasan Tawamie; Gemma M Davis; Lars Tebbe; Peter Nürnberg; Gudrun Nürnberg; Holger Thiele; Michaela Thoenes; Eugen Boltshauser; Steffen Uebe; Oliver Rompel; André Reis; Arif B Ekici; Lynn McTeir; Amy M Fraser; Emma A Hall; Pleasantine Mill; Nicolas Daudet; Courtney Cross; Uwe Wolfrum; Rami Abou Jamra; Megan G Davey; Hanno J Bolz Journal: Elife Date: 2015-09-19 Impact factor: 8.140