Microiontophoretic studies of the effects of D-1 and D-2 receptor agonists on type I caudate nucleus neurons: lack of synergistic interaction.

Several lines of evidence have suggested there may be a physiologically relevant form of synergistic interaction between D-1 and D-2 dopamine (DA) receptors located on postsynaptic neurons in the forebrain that receive a dopaminergic innervation. Because of the theoretical importance of such an interaction with respect to understanding the normal physiology of dopaminergic systems, we evaluated effects of D-1 and D-2 selective agonists, applied microiontophoretically, on the spontaneous electrical activity of a single, identifiable subpopulation of neurons within the caudate nucleus, the type I striatal neuron, in locally anesthetized, gallamine-paralyzed rats. It was observed that the D-2 receptor agonist quinpirole (QUIN) produced biphasic effects on cell firing rate. Low ejection currents significantly increased firing rate, while higher currents produced an inhibition. Similar effects were observed for the D-1 agonists SKF 38393; however, the overall excitations observed at low ejection currents were far less than those observed for QUIN. When these two agonists were applied concurrently, a simple additive effect (but not synergism) was always observed. The acute reduction of striatal levels of DA, by as much as 84% (with pretreatment with alpha-methyl-p-tyrosine, AMPT), did not alter the responsiveness of type I striatal neurons to the DA receptor agonists applied alone or in combination. These observed effects were not altered either by chloral hydrate anesthesia (in which glutamate-driven activity was studied) or by a more severe depletion of striatal DA levels (98% depletion produced by combined pretreatment with AMPT and reserpine).