Pressure exposure unmasks differences in release properties between high and low yield excitatory synapses of a single crustacean axon

The cellular mechanisms underlying the effect of high pressure on synaptic transmission at two types of synapses were studied in the opener muscle of the lobster walking leg. Excitatory postsynaptic currents (EPSCs) were recorded using a loose macropatch clamp technique at normal pressure and 3.5, 6.9 MPa helium pressure. Responses of the single excitatory axon could be grouped into two types: low yield (L) synapse exhibiting a small mean EPSC with a considerable number of failures, and high yield (H) synapse having a larger mean EPSC with very few failures. The change in several synaptic transmission parameters indicated that high pressure similarly reduced presynaptic evoked release in both L and H synapses. However, some differences in the kinetics and probability of release could be detected. A major difference was the spontaneous miniature EPSCs (mEPSCs) activity. Many of the mEPSCs, observed only in L synapses, were 'giant' (size of 2-5 q). High pressure selectively increased the frequency of the giant mEPSCs in the L synapse but had little effect on their amplitude histogram. High pressure depressed evoked synaptic transmission in both synapses by modulating the presynaptic quantal release parameters, but concomitantly enhanced spontaneous quantal release in L synapses by an unknown mechanism.