One of the difficulties for studying the mechanisms of synaptogenesis stems from the spatial unpredictability of contact formation between neurons, and the involvement of many parallel adhesive pathways mediating axon-dendrite recognition. To circumvent these limitations, we describe here a method allowing for the investigation of biomimetic synaptic contacts at controlled locations with high precision and statistics. Specifically, primary neurons are cultured on micropatterned substrates comprising arrays of micron-scale dots coated with purified synaptogenic adhesion molecules. Coating the substrates with the homophilic adhesion molecule SynCAM1 triggers the formation of functional presynaptic structures in axons, while neurexin-1β elicits postsynapses in dendrites from neurons expressing the counter receptor neuroligin-1. This assay can be combined with various optical imaging techniques, including immunocytochemistry to screen the accumulation of synaptic components, long-term live cell recordings to probe the kinetics of neurite growth and synapse differentiation, as well as high-resolution single-molecule tracking.
Keywords: Adhesion molecules; Micropatterned substrates; Neurexin; Neuroligin; SynCAM; Synapse formation.
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