Effects of Antiepileptic Agents on Homotypic Fusion of Synaptic Vesicles

We studied the effects of three antiepileptic drugs (AEDs) in a cell-free model system containing isolated synaptic vesicles (SVs) and cytosolic proteins, which allowed us to reproduce one of the stages of complex exocytosis. Ethosuximide, sodium valproate, and gabapentin intensified calcium- and Mg²⁺-ATP-induced fusion of SVs; the effect was indicative of the ability of these agents to influence the processes of simple and/or complex exocytosis in synaptic connections in the CNS structures. Antiepileptic drugs did not change the intensity of calcium-dependent fusion of liposomes and SVs treated by proteases. Therefore, the effect of AEDs can be realized via their interaction with proteins of SVs. After decrease in the level of cholesterol in the membranes of SVs using treatment by methyl-β- cyclodextrin, the ability of AEDs to activate fusion of SVs remained unchanged. Therefore, the studied AEDs act via proteins localized beyond the borders of cholesterol-enriched microdomains of the membrane. Drugs that induce convulsions (corazole and picrotoxin) did not change the characteristics of fusion of SVs under the in vitro action of AEDs. This is indicative of the absence of molecular targets for the above chemoconvulsants in the SV membranes, as compared with those in the plasma membranes of nerve terminals. According to our experiments, just proteins of SVs are functional targets for ethosuximide, sodium valproate, and gabapentin providing their anticonvulsant actions. The proposed model, which allows one to reproduce the membrane fusion, can be successfully used for the testing of drugs influencing a presynaptic link of synaptic contacts in the CNS.     

Membranotropic properties of latrotoxin-like protein: Studies on liposomes

Fusion and changes in permeability of artificial phospholipid vesicles (liposomes) caused by the influence of α-latrotoxin-like protein (L protein) from the gray matter of the bovine brain were studied using a hydrophobic fluorescent probe, R18. It was shown that L protein stimulates fusion of negatively charged liposomes. This effect becomes stronger in acidified media. The influence of L protein on the permeability of phosphatidylcholine liposome membrane is also a pH-dependent process.