Dopamine Receptor-Mediated Mechanisms Involved in the Expression of Learned Activity of Primate Striatal Neurons

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Dopamine Receptor-Mediated Mechanisms Involved in the Expression of Learned Activity of Primate Striatal Neurons

Katsushige Watanabe¹^,² and Minoru Kimura¹

¹ Faculty of Health and Sport Sciences, Osaka University, Toyonaka, Osaka 560; and ² Department of Neurosurgery, School of Medicine, Gunma University, Maebashi, Gunma 371, Japan

Watanabe, Katsushige and Minoru Kimura. Dopamine receptor-mediated mechanisms involved in the expression of learnedactivity of primate striatal neurons. J. Neurophysiol. 79: 2568-2580,1998. To understand the mechanisms by which basal ganglia neuronsexpress acquired activities during and after behavioral learning,selective dopamine (DA) receptor antagonists were applied whilerecording the activity of striatal neurons in monkeys performingbehavioral tasks. In experiment 1, a monkey was trained to associatea click sound with a drop of reward water. DA receptor antagonistswere administered by micropressure using a stainless steel injectioncannula (300 µm ID) through which a Teflon-coated tungsten wirefor recording neuronal activity had been threaded. Responses tosound by tonically active neurons (TANs), a class of neurons inthe primate striatum, were recorded through a tungsten wire electrodeduring the application of either D1- or D2-class DA receptor antagonists(total volume <1 µl, at a rate of 1 µl/5-10 min). Applicationof the D2-class antagonist, ( $-$ )-sulpiride (20 µg/µl, 58 mM, pH6.8), abolished the responses of four of five TANs examined. Inanother five TANs, neither the D2-class antagonist nor the D1-classantagonists, SCH23390 (10 µg/µl, 31 mM, pH 5.7) or cis-flupenthixol(30 µg/µl, 59 mM, pH 6.6) significantly suppressed responses.In experiment 2, four- or five-barreled glass microelectrodeswere inserted into the striatum. The central barrel was used forextracellular recording of activity of TANs. Each DA receptorantagonist was iontophoretically applied through one of the surroundingbarrels. SCH23390 (10 mM, pH 4.5) and ( $-$ )-sulpiride (10 mM, pH4.5) were used. The effects of iontophoresis of both D1- and D2-classantagonists were examined in 40 TANs. Of 40 TANs from which recordingswere made, responses were suppressed exclusively by the D2-classantagonist in 19 TANs, exclusively by the D1-class antagonistin 3 TANs, and by both D1- and D2-class antagonists in 7 TANs.When 0.9% NaCl, saline, was applied by pressure (<1 µl) or byiontophoresis (<30 nA) as a control, neither the background dischargerates nor the responses of TANs were significantly influenced.Background discharge rate of TANs was also not affected by D1-or D2-class antagonists applied by either micropressure injectionor iontophoresis. It was concluded that the nigrostriatal DA systemenables TANs to express learned activity primarily through D2-classand partly through D1-class receptor-mediated mechanisms in thestriatum.

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