It has been proposed that the combinatorial expression of γ‐protocadherins (Pcdh‐γs) and other clustered protocadherins (Pcdhs) provides a code of molecular identity and individuality to neurons, which plays a major role in the establishment of specific synaptic connectivity and formation of neuronal circuits. Particular attention has been directed to the Pcdh‐γ family, for which experimental evidence derived from Pcdh‐γ‐deficient mice shows that they are involved in dendrite self‐avoidance, synapse development, dendritic arborization, spine maturation, and prevention of apoptosis of some neurons. Moreover, a triple‐mutant mouse deficient in the three C‐type members of the Pcdh‐γ family (Pcdh‐γC3, Pcdh‐γC4, and Pcdh‐γC5) shows a phenotype similar to the mouse deficient in whole Pcdh‐γ family, indicating that the latter is largely due to the absence of C‐type Pcdh‐γs. The role of each individual C‐type Pcdh‐γ is not known. We have developed a specific antibody to Pcdh‐γC4 to reveal the expression of this protein in the rat brain. The results show that although Pcdh‐γC4 is expressed at higher levels in the embryo and earlier postnatal weeks, it is also expressed in the adult rat brain. Pcdh‐γC4 is expressed in both neurons and astrocytes. In the adult brain, the regional distribution of Pcdh‐γC4 immunoreactivity is similar to that of Pcdh‐γC4 mRNA, being highest in the olfactory bulb, dentate gyrus, and cerebellum. Pcdh‐γC4 forms puncta that are frequently apposed to glutamatergic and GABAergic synapses. They are also frequently associated with neuron‐astrocyte contacts. The results provide new insights into the cell recognition function of Pcdh‐γC4 in neurons and astrocytes.
Collybistin (CB) is a guanine nucleotide exchange factor (GEF) selectively localized at GABAergic and glycinergic postsynapses. Analysis of mRNA shows that several isoforms of collybistin are expressed in the brain. Some of the isoforms have a SH3 domain (CBSH3+) and some have no SH3 domain (CBSH3−). The CBSH3+ mRNAs are predominantly expressed over CBSH3−. However, in an immunoblot study of mouse brain homogenates, only CBSH3+ protein isoforms were detected, proposing that CBSH3− protein might not be expressed in the brain. The expression or lack of expression of CBSH3− protein is an important issue because CBSH3− has a strong effect in promoting the postsynaptic clustering of gephyrin and GABA-A receptors (GABA A Rs). Moreover CBSH3− is constitutively active; therefore lower expression of CBSH3− protein might play a relatively stronger functional role than the more abundant but self-inhibited CBSH3+ isoforms, which need to be activated. We are now showing that: (a) CBSH3− protein is expressed in the brain; (b) parvalbumin positive (PV+) interneurons show higher expression of CBSH3− protein than other neurons; (c) CBSH3− is associated with GABAergic synapses in various regions of the brain and (d) knocking down CBSH3− in hippocampal neurons decreases the synaptic clustering of gephyrin and GABA A Rs. The results show that CBSH3− protein is expressed in the brain and that it plays a significant role in the size regulation of the GABAergic postsynapse.
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