g Growth-associated protein 43 (GAP43) is known to regulate axon growth, but whether it also plays a role in synaptogenesis remains unclear. Here, we found that GAP43 regulates the aggregation of gephyrin, a pivotal protein for clustering postsynaptic GABA A receptors (GABA A Rs), in developing cortical neurons. Pharmacological blockade of either protein kinase C (PKC) or neuronal activity increased both GAP43-gephyrin association and gephyrin misfolding-induced aggregation, suggesting the importance of PKC-dependent regulation of GABAergic synapses. Furthermore, we found that PKC phosphorylation-resistant GAP43 S41A , but not PKC phosphorylation-mimicking GAP43 S41D , interacted with cytosolic gephyrin to trigger gephyrin misfolding and its sequestration into aggresomes. In contrast, GAP43 S41D , but not GAP43 S41A , inhibited the physiological aggregation/clustering of gephyrin, reduced surface GABA A Rs under physiological conditions, and attenuated gephyrin misfolding under transient oxygen-glucose deprivation (tOGD) that mimics pathological neonatal hypoxia. Calcineurin-mediated GAP43 dephosphorylation that accompanied tOGD also led to GAP43-gephyrin association and gephyrin misfolding. Thus, PKC-dependent phosphorylation of GAP43 plays a critical role in regulating postsynaptic gephyrin aggregation in developing GABAergic synapses.
Proper development of inhibitory GABAergic synapses is critical for establishing an excitatory/inhibitory balance in the neural network (1, 2). The impairment of postsynaptic GABA A receptor (GABA A R) activity is a major cause of neuronal hyperactivity, affecting cognitive development and psychosocial behaviors (3, 4). Postsynaptic surface insertion and clustering of GABA A Rs determine the efficacy of GABAergic synapses (4, 5). Gephyrin, a microtubule-associated protein, is a key scaffolding protein that requires the GABA A R ␥2 subunit for clustering GABA A Rs at the postsynaptic membrane (6, 7). The lack of neuronal gephyrin reduces postsynaptic GABA A R clustering, thereby impairing inhibitory synaptic transmission (8, 9).In central neurons, gephyrin monomers oligomerize to form a hexagonal lattice, also called gephyrin clusters, underneath the cell surface membrane to anchor postsynaptic GABA A Rs (10). However, numerous studies have shown that gephyrin is an aggregation-prone protein that forms large clumps when expressed in nonneural cells or cell-free systems (11, 12). Instead, gephyrin in neurons forms small aggregates/clusters in both the cytosol and submembrane domain for receptor clustering, suggesting a neuronal machinery that regulates gephyrin clustering. To date, a postsynaptic protein, collybistin, a GDP-GTP exchanging factor, is the only gephyrin-interacting protein that can effectively disperse gephyrin clumps into oligomeric clusters in HEK293T cells (13). Gephyrin scaffolding in neurons depends on the dynamic rearrangement of microtubules and actin microfilaments at postsynaptic sites (14,15). Whether cytoskeleton-associated proteins are involved in regulat...
