Chemical synapses are the specialized structures supporting communication between neurons in the brain and between neurons and muscles at neuromuscular junctions. They represent the elementary structures processing information transfer within neuronal networks and they rely on a precise molecular organization that was selected early during evolution.
The human brain might contain up to a million of billion synapses, which represents an ultimate challenge for precise characterization of these structures at the molecular scale. To reduce complexity, the current project uses the nematode C. elegans, a simple model organism that contains less than ten thousand synapses. Yet, C. elegans synapses are very similar to human synapses at the molecular level. This project takes advantage of powerful genetic strategies in combination with cutting-edge in vivo imaging and electrophysiology tools to identify new molecules and new mechanisms involved in synaptic formation and function.
The goal of this project has been to increase our fundamental knowledge of the synapse and to shed light on the physiopathology of several neuropsychiatric illnesses in which synaptic defects are at the core of the disease.