%0 Journal Article
%T Polarization and orientation of retinal ganglion cells in vivo
%A Flavio R Zolessi
%A Lucia Poggi
%A Christopher J Wilkinson
%A Chi-Bin Chien
%A William A Harris
%J Neural Development
%D 2006
%I BioMed Central
%R 10.1186/1749-8104-1-2
%X A key step in neuronal morphogenesis is the emergence of correctly oriented axons and dendrites. The cellular and molecular mechanisms that determine how one neurite is selected to become the axon while the others become dendrites have been studied extensively in conditions where this problem is most approachable experimentally, namely in vitro [1]. If hippocampal cells are cultured soon after their final mitotic divisions, multiple neurites emerge simultaneously at seemingly random orientations. From these young multipolar neurons, one neurite then begins to elongate preferentially, marking the beginning of polarization. It becomes the axon [2], and as it grows it inhibits the other neurites from becoming axons. They become dendrites instead. The inhibitory signal relies on the activities of the small GTPases Rac/Cdc42 and Rho [3,4] and on the localized inactivation of GSK-3¦Ā [5,6]. Proteins normally associated with the apical junctional complexes of epithelial cells, such as Par-3, Par-6 and atypical protein kinase C (aPKC) have a role in polarization in vitro. Aided by adenomatous polyposis coli and KIF3A (a kinesin superfamily protein), proteins that travel along microtubules, these apical components accumulate at the tips of growing axons. Interference with the activity of any of these proteins compromises polarization [7-9]. The centrosome, acting as a microtubule organizing center, also has a role in axon formation in vitro [10], and recent evidence suggests that its position determines of the site of axon emergence [11].In dissociated cell cultures, neurons develop in the presence of very scarce external cues, and so must perforce break symmetry intrinsically. In vivo, however, neurons are generated within a highly oriented three-dimensional neuroepithelium. In such a situation, differentiating neurons may depend on external cues for polarization. In support of this idea, Rolls and Doe [12] demonstrated that, in Drosophila mutants lacking the apical junction
%U http://www.neuraldevelopment.com/content/1/1/2