To test AAK1′s functional role, we expressed AAK1 kinase-dead (AAK1-KD) K74A (Conner and Schmid, 2003), the AAK1 nonphosphorylatable mutant S635A (AAK1-SA) or the AAK1 phospho-mimetic mutant S635D (AAK1-SD), together with GFP in dissociated hippocampal neurons. A small subset of neurons with very high expression of mutant AAK1 looked unhealthy and were not included in the analysis. Similar to the Epigenetics inhibitor result for NDR1/2 loss of function, AAK1-KD and AAK1-SA had increased branching within 50 μm from the
soma (Figures 6A–6C). In contrast, AAK1-SD decreased branching (Figures 6A, 6B–6C) similar to NDR1-CA. Dendrite length was also increased in AAK1-KD and reduced in AAK1-SD mutants (Figure 6D), in a similar way to the effect caused by manipulations of NDR1/2 activity. AAK1 siRNA, which knocked down AAK1 partially (Figures S5A and S7A), increased dendrite branching and length; this effect was rescued with siRNA-resistant Vorinostat AAK1 (Figures 6C and 6D). The dendritic spines appeared normal in AAK1-KD and AAK1-SA mutants; however, neurons expressing AAK1-SD at high levels showed a reduction in dendritic spine density (Figures S5F and S5G). Thus, although overactive NDR1 and AAK1-SD could lead to the elimination of dendritic spines, most likely other NDR1/2 substrate(s) contribute to mushroom spine
formation by NDR1/2. To explore if AAK1 is downstream of NDR1/2 in dendrite development, we performed epistasis experiments. Total plasmid DNA concentration was kept constant between conditions. Control neurons were transfected with GFP expressing empty siRNA plasmid (pGmir), together with HA expressing empty plasmid (prk5). To observe the effect of NDR1/2 loss of function, we transfected NDR1siRNA and NDR2siRNA together with equal amounts of empty prk5 Astemizole vector. This treatment caused an increase
in proximal dendrite branching (Figures 6E and 6F), total dendrite branching (Figure 6G), and length (Figure 6H) as was expected. In order to test epistasis, NDR1siRNA and NDR2siRNA were co-transfected with the AAK1-SD-HA construct in prk5 vector. This treatment led to the rescue of dendrite phenotypes induced by NDR1siRNA + NDR2siRNA (Figures 6E–6H). In complementary experiments, we transfected NDR1-CA with GFP expressing empty siRNA plasmid and observed robust reduction in proximal dendrite branching (Figures 6E and 6F), total dendrite branching (Figure 6G), and length (Figure 6H). The reduction in dendrite branching and length with NDR1-CA was more pronounced than in previous results because of the higher plasmid concentration used here. These effects of NDR1-CA were partially rescued with co-expression of AAK1siRNA (instead of empty siRNA plasmid), indicating that AAK1 activity was necessary to limit dendrite branching. These experiments indicate that AAK1 is downstream of NDR1 for limiting dendrite branching.