Zusammenfassung
Eine strikte, räumliche und zeitliche Kontrolle der Aktinpolymerisation ist essenziell für eine Vielzahl zellulärer Prozesse. Drosophila-Mutanten haben zu neuen Einblicken in die in vivo-Regulation der Aktindynamik geführt.
Abstract
A tight spatio-temporal coordination of the machineries controlling actin polymerization is essential for a variety of cellular processes. Drosophila mutants have greatly contributed to our understanding of actin dynamics in vivo.
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Literatur
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Christina Gohl 2001–2006 Biologiestudium an der Universität Münster; dort 2006 Diplomarbeit in Entwicklungs-/Zellbiologie und 2010 Promotion in Entwicklungs-/Zellbiologie.
Thomas Zobel 2003–2009 Biologiestudium an der TU Braunschweig; dort 2009 Diplomarbeit in Entwicklungsgenetik. Seit 2009 Doktorand an der Universität Münster in Entwicklungs-/Zellbiologie.
Sven Bogdan 1991–1996 Biologiestudium an der Universität Bochum; dort 1997 Diplomarbeit in Zellbiochemie. 2000 Promotion in Entwicklungs-/Zellbiologie am Universitätsklinikum Essen. 2000–2005 Wissenschaftlicher Mitarbeiter/Assistent (C1) am Institut für Neuro- und Verhaltensbiologie der WWU Münster; 2006 Unabhängiger Nachwuchsgruppenleiter, Institut für Neuro- und Verhaltensbiologie. 2009 Habilitation (Venia legendi in Zoologie/Neurobiologie).
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Gohl, C., Zobel, T. & Bogdan, S. Molekulare Kontrolle der Aktindynamik in vivo bei Drosophila . Biospektrum 17, 28–31 (2011). https://doi.org/10.1007/s12268-011-0005-7
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DOI: https://doi.org/10.1007/s12268-011-0005-7