, 2005). Although the physiological significance of this form of plasticity is not fully delineated, these data suggest that vesicles in muscle fuse and release a soluble signal that traverses the synaptic cleft and signals to the presynaptic release machinery. Some of the first evidence that synaptic see more plasticity requires
postsynaptic exocytosis came from experiments where various factors that inhibit SNARE-mediated membrane fusion were infused into postsynaptic neurons via a recording pipette (Lledo et al., 1998). Each of these factors, which included N-ethylmaleimide, botulinum toxin B, and a short peptide designed to interfere with the binding of NSF to SNAP, blocked LTP triggered by stimulating nearby Schaffer collateral axons. This early observation led
to a model where intradendritic vesicles harboring AMPA-type glutamate receptors fuse with the plasma membrane upon LTP induction. Synaptic strength increases as newly inserted AMPA receptors become incorporated into synapses ( Newpher and Ehlers, 2008). In addition to functional selleck chemicals plasticity, several studies have shown that postsynaptic exocytosis is critical for morphological plasticity at glutamatergic synapses ( Kopec et al., 2006, Kopec et al., 2007, Park et al., 2004, Park et al., 2006 and Yang et al., 2008). Dendritic spines, the micron-sized protrusions ever contacted by axonal terminals at excitatory synapses, stably increase their volume by ∼2-fold following NMDA receptor activation ( Matsuzaki et al., 2004). Infusion of botulinum toxin B, which cleaves VAMP family SNARE proteins, or expression of dominant-negative SNARE proteins in postsynaptic neurons blocks stimulus-induced spine growth ( Kopec et al., 2007, Park et al., 2006 and Yang et al., 2008), indicating that morphological plasticity requires membrane fusion. More recent experiments have sought to define the identity of the intracellular membrane stores, location of activity-triggered
exocytosis, the cargo responsible for synapse potentiation, and the SNARE molecules involved in postsynaptic vesicle fusion. Serial reconstruction electron microscopy studies demonstrated the presence of membrane-bound structures, including recycling endosomes, throughout dendrites and in a large fraction of dendritic spines (Figure 1B) (Cooney et al., 2002). This observation, along with experiments demonstrating that AMPA receptors are endocytosed and reinserted upon synaptic activation, suggested that dendritic recycling endosomes are the internal membrane stores mobilized to the plasma membrane in response to LTP-inducing stimuli (Beattie et al., 2000, Carroll et al., 1999, Ehlers, 2000 and Lüscher et al., 1999).