In addition, we also performed coculture experiments between cort

In addition, we also performed coculture experiments between cortical neurons expressing PCDH17-EGFP and CHO cells selleck inhibitor expressing either PCDH17-myc or PCDH10-myc. A significant portion of PCDH17-EGFP in neurons was localized next to PCDH17-myc in CHO cells at contact

points, but not PCDH10-myc in CHO cells (Figure 4E). Taking these results together with the finding that PCDH17 is mainly localized at both excitatory and inhibitory perisynaptic sites (Figure 3), we conclude that PCDH17 mediates homophilic intercellular interactions at synapses in basal ganglia (Figure 4F). To examine the physiological role of PCDH17, we generated PCDH17−/− mice ( Figure S3A). The success of the procedure was confirmed by Southern blot (data not shown) and PCR analysis ( Figure S3B). We confirmed the absence of the PCDH17 protein in PCDH17−/− mice by immunoblotting and immunostaining ( Figures S3C and S3D). The loss of PCDH17 in PCDH17−/− mice was also confirmed by immunoelectron microscopy (

Figure S3E). Quantitative analysis in the anterior Staurosporine manufacturer striatum verified a 96% reduction in numbers of immunogold particles in comparison with wild-type mice. The numbers of PCDH17−/− mice produced followed a Mendelian segregation pattern and these mice attained normal body size and appeared healthy (data not shown). Histological analysis using Nissl-stained coronal sections from the central nervous system from PCDH17−/− mice did not show any gross abnormalities in cytoarchitecture

( Figure S3F). In addition, the absence of PCDH17 did not find more affect the expression of synapse-specific markers, including N-cadherin, Synaptophysin, VGLUT1, PSD-95, NMDA receptor subunits, and AMPA receptor subunits in the anterior and posterior striatum ( Figure S3G). We examined whether axonal projections were abrogated in the absence of PCDH17. Immunostaining analyses showed that PCDH17 deficiency did not affect overall axonal projections, including corticothalamic/thalamocortical projections, striatopallidal/striatonigral projections, and nigrostriatal projections ( Figures S4A and S4B). Therefore, in contrast to the abnormal axonal projection phenotypes observed in PCDH10−/− mice ( Uemura et al., 2007), the overall circuitry in basal ganglia appeared to be intact in PCDH17−/− mice. We next evaluated whether ablation of PCDH17 affected the topographic connections within the corticobasal ganglia circuits. In retrograde tracing, local injections of CTb-Alexa Fluor 488 into the anterior striatum and CTb-Alexa Fluor 555 into the posterior striatum resulted in the labeled signals in medial prefronatal cortex and motor cortex, respectively, in both wild-type and PCDH17−/− mice ( Figure S4C). Thus, PCDH17 deficiency did not affect projection topography in corticostriatal pathways.

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