Presynaptic filopodia form kinapses and modulate membrane mechanics for synchronous neurotransmission and seizure generation

The structural stability of synapses directly contrasts with their functional plasticity. This conceptual dichotomy is explained by the assumption that all synaptic plasticity is generated via either electrical and/or biochemical signaling. Here, we challenge this dogma by revealing an activity-dependent presynaptic response that is physical in nature. We show that dynamic filopodia emerge during action potential discharge and transiently deform synaptic boutons to enhance connectivity. Filopodia generation requires neuronal activity, calcium and actin, and occurs in intact brain circuits and human brain. Mechanistically, their extension preserves synchronous neurotransmitter release by increasing presynaptic membrane tension. However, filopodia generation becomes maladaptive during dysregulated brain activity, exacerbating seizures in vivo . Therefore, we provide direct evidence that presynaptic mechanical forces determine the extent and timing of synaptic signals.