Short-term plasticity at retinogeniculate synapses depends on synaptic strength

Relay neurons of the dorsal lateral geniculate nucleus (dLGN) receive convergent inputs from retinal ganglion cells (RGCs). Retinogeniculate synapses exhibit a highly skewed distribution of synaptic strength, with a few strong inputs and many weak ones. Strong synapses are thought to dominate relay neuron activity. However, the contribution of individual inputs might not just depend on strength but also on short-term plasticity Using minimal stimulation recordings in acute mouse brain slices, we analyzed the electrophysiological properties of individual retinogeniculate synapses. We observed a robust inverse correlation between synaptic strength and short-term plasticity: weak synapses showed facilitation, whereas strong synapses exhibited pronounced depression. This was consistent with increasing vesicle release probability and enhanced AMPA receptor desensitization at stronger synapses. Analysis of synaptic current kinetics further suggested that variability in synaptic strength reflects not only differences in synapse size and AMPA receptor content but also differences in the electrotonic distance of synapses from the soma. Together, these results reveal systematic heterogeneity in both presynaptic and postsynaptic properties of retinogeniculate synapses. Therefore, the relative contribution of weak and strong inputs to relay neuron firing is likely activity-dependent, with strong synapses dominating when RGCs fire few action potentials and weaker inputs contributing more during sustained or high-frequency firing with several action potentials.