Effects of dopaminergic agonists and antagonists on [3H]apomorphine binding to striatal membranes: sulpiride lack of interactions with positive cooperative [3H]apomorphine binding

Interaction of nicotine with dopaminergic mechanisms assessed through drug discrimination and rotational behaviour in rats

Biochemical and electrophysiological studies have suggested that nicotine may interact with dopaminergic systems so as to enhance the release and utilization of dopamine. The functional significance of these effects has been assessed using drug discrimination and rotational behaviour in rats. The dopamine antagonists haloperidol and Sch 23390 attenuated the discriminative stimulus effect of nicotine and reduced overall rates of responding. In contrast, droperidol and pimozide were without significant effect on discrimination of nicotine at doses that reduced response rates. There was partial generalization from nicotine to the dopamine D-1 agonist SKF 38393. In rats with unilateral, 6-hydroxydopamine lesions of the nigrostriatal dopamine pathway, nicotine produced rotation towards the side of the lesion, a characteristic effect of indirectly acting dopamine agonists such as amphetamine. The nico tinic-cholinergic antagonist mecamylamine, and haloperidol, blocked rotation produced by nicotine. A dose of nicotine that was too small to produce amphetamine-like effects itself enhanced both the discriminative stimulus and the rotational behaviour produced by amphetamine. However, mecamylamine did not weaken the discriminative effect of amphetamine. The results suggest that there may be a minor component of the nicotine discriminative stimulus that is mediated, indirectly, through a dopaminergic mechanism. There also appears to be a facilitatory, nicotinic influence on behavioural functions linked to the dopamine system.

D-2 dopamine receptor synthesis and turnover in rat striatum

Direct injection of phenoxybenzamine into rat striatum inhibited apomorphine-induced stereotyped behavior. This inhibition corresponded well with the inhibition of D-2 dopamine receptor labelling with [3H]spiroperidol. Both the behavioral response and the receptor level were completely restored within 5 days after the injection. The recoveries of both were blocked by cycloheximide. The rate of synthesis and half-life of the D-2 receptor associated with the stereotyped behavior were calculated to be 6.9 fmol/mg protein per h and 28 h, respectively.

Effects of pertussis toxin on D2-dopamine receptor in rat striatum: evidence for coupling of Ni regulatory protein with D2-receptor

It is well established that a pertussis toxin, islet activating protein (IAP), interacts directly with the Ni regulatory protein involved in the receptor-adenylate cyclase system. In this study we investigated the effect of the toxin on the dopaminergic function of the central nervous system in conjunction with the adenylate cyclase system. Direct bilateral microinjection of the toxin into rat striatum reduced the stereotyped behavior induced by apomorphine. This inhibitory effect was observed even 40 h after administration of the toxin, whereas the inhibition by haloperidol disappeared within 15 h. Toxin administration did not influence either the Bmax or affinity of specific binding of [3H]spiroperidol to the striatal membrane. However, it increased the IC50 value of apomorphine for the specific binding of [3H]spiroperidol. GTP (10(-4) M) had little effect on the apparent affinity of apomorphine to the [3H]spiroperidol binding sites in IAP-treated membrane, though an effect was clearly observed in untreated membrane. [3H]Spiroperidol binding sites were increased 34 +/- 8% (n = 4) on chronic treatment of haloperidol for 2 weeks. On the contrary, on long-term administration of IAP the ligand binding sites were decreased by 25 +/- 10% (n = 4). These results indicate that pertussis toxin can interact with the Ni protein coupled with striatal D2-dopamine receptor. Inhibition of the coupling between Ni protein and the D2-dopamine receptor attenuated the manifestation of rat stereotyped behavior. Furthermore, chronic administration of dopamine antagonist resulted in the up-regulation of the D2-dopamine receptor, while long-term inhibition of coupling between the D2-dopamine receptor and Ni regulatory protein reduced the amount of receptors.

Evidence that apomorphine and pergolide induce rotation in rats by different actions on D1 and D2 receptor sites

Apomorphine and the ergot derivative pergolide induced dose-dependent contralateral rotation in rats with unilateral 6-hydroxydopamine denervation of the ascending dopamine pathways. This was interpreted as an action on supersensitive receptors. However, large differences were found when comparing apomorphine and pergolide dose-response curves as well as the patterns of rotational behaviour the compounds elicited. Pergolide had a steep dose-response curve, while apomorphine had a flatter curve reaching a plateau at the dose of 1 mg/kg s.c. In doses higher than 1 mg/kg, apomorphine induced self-mutilation, while this was infrequent after pergolide. Apomorphine induced a two-peak pattern of rotation that never occurred when the same rats were tested with the ergot derivative. Both drugs induced dose-dependent ipsilateral rotation in animals with unilateral striatal kainic acid lesions but at doses 100 times higher. This effect was interpreted as an action on normosensitive receptors situated on the intact side. The differences between apomorphine and pergolide may be explained in terms of actions on different dopamine receptors, since the agonists were differently inhibited by neuroleptics acting on D1- or D2-type receptors. The D1/D2 antagonist cis-flupenthixol blocked both apomorphine and pergolide with similar potency, while sulpiride, a substituted benzamide devoid of any effect on D1 receptors, was a poor inhibitor of the apomorphine response. In contrast, sulpiride blocked pergolide rotation at doses 1000 times lower than those needed to block apomorphine rotation. Our results suggest the existence of functionally distinct sites related to the D1/D2 receptor classification.

Ascorbic acid and membrane ageing: critical determinants of the in-vitro binding of [3H]ADTN to rat striatal tissue

Tritiated (+/-)-2-amino-6,7-dihydroxy-1,2,3,4-tetrahydronaphthalene [( 3H]ADTN), binding (0.125-4.0 nM) to rat striatal membranes was investigated using Tris-HCl buffer containing Na2EDTA, nialamide and varying concentrations of ascorbic acid. In the absence of ascorbic acid [3H]ADTN exhibited a high affinity (KD 1.26 nM) saturable binding (Bmax 138 fmol mg-1 protein) (Scatchard analysis). This was not modified by 10(-6) or 10(-5) M ascorbic acid used immediately or 60 min after preparation. However, 10(-4) M ascorbic acid added (within) 15 min after its preparation reduced the number of bindings sites and added 60 min after it also reduced affinity. Ascorbic acid 5.7 mM reduced affinity whether used within 15 min or 60 min of its preparation. When ascorbic acid 10(-4) M was used within 15 min of preparation, and membranes were used immediately, the binding of 2 nM [3H]ADTN was specifically displaceable by nM or sub-nM concentrations of dopamine agonists and antagonists. However, when membranes were used 1-2 h after their preparation there was an increasing loss of the high affinity binding sites displaceable by sub-nM concentrations of (+/-)-ADTN. Thus. [3H]ADTN can be shown to exhibit high affinity stereoselective binding to rat striatal membranes when these are freshly prepared and the assay is performed using Tris-HCl buffer containing nialamide. Na2EDTA and 10(-4) M ascorbic acid prepared within 15 min of use. The characteristics of this binding can be markedly modified if the concentration of ascorbic acid is increased, if its preparation time is extended, or if the membranes are allowed to 'age'.

Selective labelling of dopamine (D2) receptors in rat striatum by [3H]domperidone but not by [3H]spiperone

Specific binding of [3H]spiperone and [3H]domperidone, displaceable by 1 microM d-butaclamol, was examined in rat striatal membranes. Initial saturation and displacement experiments indicated that [3H]spiperone bound to more sites than [3H]domperidone and that, whilst all displacing drugs were more potent against [3H]domperidone, this difference in potency was greatest for dopamine agonists and specific antagonists and least for 5HT-related drugs. Sulpiride displaced [3H]spiperone biphasically, and was used at a concentration of 50 microM to examine two classes of [3H]spiperone binding: site 1 displaceable by sulpiride, and site 2 displaceable by butaclamol but not by sulpiride. Site 1 had twice the capacity of site 2 and ten times the affinity for [3H]spiperone. Dopaminergic drugs displaced preferentially from site 1, whilst 5HT-related drugs were more potent against site 2. GTP reduced the potency of dopamine, noradrenaline and, to a lesser extent, 5HT at site 1, but had no effect at site 2. [3H]Domperidone sites had the same capacity as [3H]spiperone site 1, and dopamine, noradrenaline and 5HT, in the absence or presence of GTP, and sulpiride had essentially identical affinities for [3H]domperidone sites and [3H]spiperone site 1. It is concluded that [3H]domperidone and [3H]spiperone label an identical population of dopamine (D2) receptors, whilst [3H]spiperone also labels a substantial number of non-dopamine sites, at least some of which are 5HT-related. [3H]spiperone also labels a substantial number of non-dopamine sites, at least some of which are 5HT-related. [3H]Domperidone is the better radioligand for dopamine receptors.

Multiple postsynaptic dopamine receptors and behavioral manifestation

Previously we demonstrated the existence of non- and positive-cooperative dopamine receptors in rat striatum in [3H] apomorphine binding experiments. Non-cooperative sites were sensitive to the inhibition of sulpiride while cooperative sites were not. In the present study results dealing with the involvement of those two types of postsynaptic dopamine receptors in different behavior manifestations is shown employing lisuride hydrogen maleate (LHM). LHM elicited contralateral turnings in 6-hydroxydopamine lesioned rats unilaterally in the striatum whereas it caused ipsilateral turnings in kainic acid lesioned rats as was observed following the administration of apomorphine. Furthermore, the effect of LHM on rotating behavior was abolished by the pretreatment with sulpiride. On the other hand, LHM inhibited apomorphine induced stereotyped behavior whereas the sulpiride failed to block it. These results suggested the dual action of LHM on multiple postsynaptic dopamine receptors. The results also indicated that non-cooperative postsynaptic dopamine receptors are involved in rotating behavior while cooperative receptors participate in the elicitation of stereotypy.