This suggests that polarization defects had impeded the radial migration of
these neurons. The polarization defects resulting from downregulation of NP1 may depend on the level of NP1-siRNA expression in various progenitor cells. Assuming that the level of EGFP expression correlated with that of NP1-siRNA, we measured the EGFP fluorescence intensity of individual neuronal somata of various morphologies at different cortical layers in E21 rat embryos. The results (Figure 6H) suggest that the level of NP1-siRNA expression correlated well with the severity of the learn more polarization defects, with neurons that exhibited multipolar morphology at the SVZ showing higher levels of GFP expression, in comparison to those exhibiting bipolar morphology
at the IZ and CP (Figure 6Hb). Interestingly, in cells expressing control siRNA, the opposite was found for GFP expression—higher in bipolar cells in the IZ/CP than multipolar cells in the SVZ (Figure 6Ha). The latter finding suggests that for NP1-siRNA expressing neurons, the difference in the level of NP1-siRNA expression between normally migrating bipolar cells and polarization-defective PD0325901 concentration multipolar cells could be even higher than that indicated by the EGFP expression. In this study, we examined the role of Sema3A in polarizing axon/dendrite differentiation in cultured hippocampal neurons and showed that localized exposure of an undifferentiated neurite to Sema3A induces its differentiation into the dendrite, via local suppression of axon development. This suppression is mediated by Sema3A-induced elevation of cGMP/PKG signaling that downregulates cAMP/PKA-dependent LKB1 and GSK-3β Histone demethylase phosphorylation, which is essential for axon formation. In addition to this local axon suppression effect, Sema3A also promotes dendrite
growth. Furthermore, downregulation of Sema3A signaling in developing cortical neurons in vivo resulted in severe polarization defects and reduced length of the leading process, the apical dendrite, in support of the notion that Sema3A may regulate axon/dendrite polarity during the early phase of neuronal development by both suppressing axon-specific cAMP/PKA-dependent processes and promoting dendrite-specific cGMP/PKG-dependent functions. Axon/dendrite differentiation during neuronal polarization is a coordinated process, as exemplified by the formation of a single axon and multiple dendrites in cultured hippocampal neurons (Dotti et al., 1988). In most studies using these cells, the focus has been on the process of axon differentiation, with the implicit assumption that specification of the axon of one neurite determines the fate of all other neurites as dendrites. In this “axon dominance” view, the first event of neuronal polarization is the emergence of a localized signal for axon specification in one neurite.