Studies on synaptic transmission in spinal cord cultures: A comparison of postsynaptic actions of classical neurotransmitters with the peptides

Abstract

The postsynaptic action of the classical neurotransmitter noradrenaline (NA), the reversal potential of the excitatory postsynaptic potential (EPSP) and the effects of divalent cations on EPSPs in dissociated spinal cord cultures are described. In co-cultures of locus coeruleus explant and spinal cord cells, it was found that NA could mimic the response evoked by stimulation of the explant on the spinal cord cells surrounding the explants. Both depolarization and hyperpolarization responses were observed. On a few occasions, a biphasic response consisting of a hyperpolarization followed by a depolarization was observed. The depolarizing response was associated with an increase in input resistance of the membrane. This would suggest that NA may have a facilitatory effect on synaptic transmission. The depolarizations were antagonized by the α-antagonist piperoxane, and were not affected by the β-antagonist propranolol at the concentrations tested, indicating that the receptor mediating these responses is of the α-type. The reversal potential for dorsal root ganglion and spinal cord cells was +8±3.2 mV (mean±s.e.m.), and that for spinal cord and spinal cord cells was −4±4.3 mV (mean±s.e.m.). These values are different from those previously reported for glutamate in spinal cord cultures. The effects of high and low concentrations of calcium ions on quantal output and mean quantal amplitude or quantal size of the EPSP were further examined. As expected, the cation had an effect mainly on the release process: increasing the concentration of calcium increased the amount of neurotransmitter released, while reducing the concentration of calcium reduced release. Quantal size was slightly or not affected by alteration of external calcium. In comparing the postsynaptic actions of classical neurotransmitters to those of peptides, there is apparently no evidence that the actions of the two groups of agents on central neurons are different. It appears, however, that the peptides generally elicit responses at lower concentrations than the classical neurotransmitters. Further experimentation is required to fully elucidate the actions of peptides on mammalian central neurons.