D1-D2 Interaction in Feedback Control of Midbrain Dopamine Neurons

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Volume 17, Number 20, Issue of October 15, 1997 pp. 7988-7994
Copyright ©1997 Society for Neuroscience

D1-D2 Interaction in Feedback Control of Midbrain Dopamine Neurons

Wei-Xing Shi, Paula L. Smith, Chen-Lun Pun, Barbara Millet, and Benjamin S. Bunney
Department of Psychiatry, Yale University School of Medicine, New Haven, Connecticut 06510

ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
FOOTNOTES
REFERENCES

ABSTRACT

Dopamine (DA) D1-like receptors are present in pathways implicated in feedback control of midbrain DA neurons. However, stimulationof these receptors either produces no effect on DA cells, or theeffect is inconsistent. It is possible that the expression ofa D1 feedback effect requires co-activation of D2-like receptors.To test this hypothesis, we recorded extracellularly the spontaneousactivity of nigral DA cells in a low cerveau isolé rat preparation.SKF38393 and dyhydrexidine, two D1 agonists, were administeredsystemically to animals pretreated with different doses of theD2 agonist quinpirole. Supporting the hypothesis, the two D1 agonistsconsistently inhibited DA cells in animals given high doses ofquinpirole ( $>=$ 40 µg/kg, i.v.). However, no significant D1 effectwas observed in animals pretreated with only low doses ( $<=$ 20 µg/kg)of quinpirole. Because low doses of D2 agonists preferentiallyact on DA autoreceptors, and because the D1 inhibition persistedin animals whose DA autoreceptors were blocked by intranigralapplication of raclopride, our results suggest that the expressionof D1 feedback inhibition requires co-activation of D2-like receptorson DA target neurons, instead of DA neurons themselves. Theseresults, together with the finding that chloral hydrate completelyblocked the D1 inhibition, may explain why previous studies havefailed to show a consistent D1 effect on DA cells and suggestthat drugs designed to act specifically on one subtype of DA receptormay, via feedback pathways, influence the action of endogenousDA on other DA receptor subtypes as well.
Key words: DA neuron; feedback pathway; D1; D2; synergistic; SKF38393; dyhydrexidine; substantia nigra; striatonigral; single-unit recording

INTRODUCTION

The activity of midbrain DA neurons is regulated by short and long feedback pathways. The short feedback pathways, mediatedby inhibitory D2-like autoreceptors, have been studied extensively.Little is known, however, about the long feedback pathways. Bydefinition, the long feedback pathways involve DA receptors locatedon neurons postsynaptic to DA terminals. For substantia nigra(SN) DA cells, one such pathway may involve striatonigral GABAergicneurons. These neurons receive direct synaptic input from DA terminals(Freund et al., 1984; Caille et al., 1996) and project to theSN (Bunney and Aghajanian, 1976a), where their terminals makedirect synaptic connections with DA cells (Nitsch and Riesenberg,1988; Bolam and Smith, 1990; Yung et al., 1995; Caille et al.,1996). Consistent with the presence of the striatonigral feedbackpathway, the GABA antagonist picrotoxin has been shown to blockthe inhibition of SN DA neurons induced by the indirect DA agonistamphetamine, and lesions of the striatonigral pathway attenuatethe ability of amphetamine to inhibit DA neurons (Bunney and Aghajanian,1976b, 1978).

However, despite the evidence for their presence, the way long feedback pathways operate is still controversial. One issueconcerns the role of D1-like receptors. According to anatomicalstudies, D1-like receptors should play a major role in the striatonigralpathway because they are the main DA receptors expressed in striatonigralneurons (Yung et al., 1995). Electrophysiologically, however,only D2-like receptor agonists have been shown to have an effecton DA cells. Selective activation of D1-like receptors produceseither an inconsistent effect or none at all (Carlson et al.,1987; Huang and Walters, 1992; Sun et al., 1993).

A number of electrophysiological, biochemical, and behavioral studies have shown that the expression of some DA effects requiresactivation of both D1- and D2-like receptors (e.g., Walters etal., 1987; White, 1987; Bordi and Meller, 1989; Wachtel et al.,1989; Bertorello et al., 1990). It is thus possible that the expressionof the D1 feedback effect also requires concurrent activationof D2-like receptors. To test this hypothesis, we made extracellularrecordings from SN DA neurons in a low cerveau isolé rat preparationand determined whether co-administration of a D2 agonist couldenable a D1 agonist to produce an effect on DA cells.

Some results were reported previously in abstract form (Smith et al., 1994).

MATERIALS AND METHODS
Animal preparation. All procedures were performed in accordance with those outlined in the Guide for the Care and Use of LaboratoryAnimals published by the United States Public Health Service andapproved by the Yale Animal Care and Use Committee. Male SpragueDawley rats weighing between 160 and 300 gm were used. Previously,general anesthesia, including that induced by chloral hydrate,was shown to suppress the activity of striatal neurons (Kellandet al., 1988) and to block some DA receptor-mediated effects,including the D1 effect on nigral DA neurons in reserpinized animalsand on subthalamic neurons (Huang and Walters, 1992; Kreiss etal., 1996). Because of this, most experiments were performed ina low cerveau isolé preparation. However, for comparison, a fewexperiments were performed in chloral hydrate-anesthetized animals(400 mg/kg, i.p., with supplemental doses administered via thelateral tail vein). In the low cerveau isolé experiments, ratswere initially anesthetized with halothane (Halocarbon Laboratories)and locally anesthetized by infiltration of the long-acting localanesthetic mepivacaine hydrochloride (2%; Winthrop Pharmaceuticals)at all pressure points and incision sites. The brainstem was thentransected using a method similar to that described previously(Sesack and Bunney, 1989). Briefly, a small burr hole was drilled1 mm caudal to the lamboidal suture and 1 mm medial to the bonyridge at the lateral edge of the skull. A flattened 30 gauge,0.5 inch needle was inserted at a 30° angle relative to the corticalsurface and rotated, parallel to the lamboidal suture, until theneedle was at a 90° angle (Fig. 1). Halothane anesthesia was discontinuedfor at least 30 min before beginning experiments. In all experimentsbody temperature was maintained at 35-38°C with a heating pad.
Fig. 1. Diagram illustrating the position of brainstem transection for the low cerveau isolé preparation. A, Sagittal view of a ratbrain showing the site of transection between the pons and themedulla oblongata (1 mm posterior to the lambda, indicated bythe thick line). B, Coronal view of the transected areas (shaded)through the cerebellum and the brainstem. Thick lines illustratethe initial and final positions of the transection knife (a flattenedneedle). See Materials and Methods for details. Figures are redrawnfrom the rat atlas of Paxinos and Watson (1997).
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Electrophysiological recording. Single-unit activity of SN DA cells was recorded as described previously (Bunney et al., 1973;Grace and Bunney, 1980, 1983). Glass microelectrodes were madeusing a Narishige (Tokyo, Japan) electrode puller and filled witha 1 M NaCl solution containing 2% pontamine sky blue dye. Thetip of the electrode was broken back under a microscope untila diameter of between 1 and 2 µm was obtained. The resistanceof the electrode measured between 5 and 15 M $Omega$ . A small burr holewas drilled above the SN (3.0 mm anterior to the lamboidal sutureand 2.0 mm lateral to the midline). The electrode was lowered6.5-8.5 mm below the cortical surface. Electrical signals wereamplified and sent to a personal computer (DECpc 450ST) via aLab-PC⁺ (National Instrument, Austin, Texas). Spike activity was continuouslydisplayed on the computer screen. Interspike intervals and firingrate were collected on-line using software written by one of theauthors (W.S.) using LabView (National Instrument). DA neuronswere identified based on well established criteria (Bunney etal., 1973; Grace and Bunney, 1980, 1983). To allow histologicalexamination of the recording site, a spot of dye was injectedat the end of the recording by passing a $-$ 30 µA current throughthe electrode for 15-20 min.

Drugs. Unless stated otherwise, most drugs were dissolved in distilled water and administered intravenously through the lateraltail vein. In some experiments, raclopride (RAC) was locally appliedvia a Hamilton 701 syringe (1-5 µg · µl¹ · min¹ for 2 min, controlled by a syringe pump) to the area slightlyabove the SN (6.0-6.5 mm below the cortical surface). To minimizethe back flow, the syringe was removed 5 min after ejection. Drugsused in this study and their sources were SKF38393 hydrochloride[Research Biochemicals (RBI), Natick, MA], dyhydrexidine (DHX;Interneuron Pharmaceuticals, Lexington, MA), (+)-SCH23390 hydrochloride(RBI), SCH39166 (Schering-Plough, Kenilworth, NJ), raclopride(Astra, Sodertalje, Sweden), quinpirole (Eli Lilly, Indianapolis,IN), and haloperidol (dissolved in a preprepared injection solution;McNeil Pharmaceuticals, Spring House, PA).

Statistics. The statistical significance of the effect of each drug was determined by comparing the firing rates (raw data,i.e., spikes/10 sec) before and after drug injection using a pairedt test. All numerical data were expressed as mean ± SEM.

RESULTS

Effect of D1 agonists alone on SN DA neurons
In nine identified DA neurons, SKF38393 (10 mg/kg) was administered intravenously in either a single dose (n = 3) or multipledoses (5 and 5 mg/kg, n = 2; or 2.5, 2.5, and 5 mg/kg, n = 4).Consistent with a previous study (Carlson et al., 1987), the D1agonist failed to produce a consistent effect on DA cells. Fivecells showed an increase in firing rate (34.5 ± 9.9% of baseline,ranging from 16.7 to 70.8%), and four showed a decrease (42.7± 19.2% of baseline, ranging from 18.2 to 100%). To determinewhether the effects of SKF38393 were mediated by D1-like receptors,the D1 antagonist SCH23390 (20-100 µg/kg) was administered afterSKF38393 in five cells. In four cells, SCH23390 showed no effecton either SKF38393-induced excitation (n = 2) or inhibition (n= 2). In one cell, however, the inhibitory effect (18.2% of baseline)of SKF38393 was reversed.

To test further whether the variable effect of SKF38393 is related to D1-like receptor stimulation, the new full D1 agonistDHX was administered to six other SN DA neurons (1 mg/kg in asingle dose). No significant change in the firing rate was observedin five of six cells (<10% change of baseline). In one cell, DHXproduced an 18% inhibition of basal activity. Overall, the effectof DHX was statistically not significant (4 ± 3% decrease in baseline;p = 0.697; n = 6, paired t test).

Effect of D1 agonists on DA neurons pretreated with a D2 agonist
To test whether activation of D2-like receptors is necessary for the expression of a D1 effect, nine DA cells were exposedto the D2-selective agonist quinpirole (administered i.v.) beforethe injection of SKF38393. Because quinpirole inhibits DA cellsby itself, low doses (11.7 ± 2.2 µg/kg, ranging from 5 to 20 µg/kg)were injected to avoid a complete inhibition. In seven cells,SKF38393 (10 mg/kg, n = 6; 20 mg/kg, n = 1), after quinpirole,produced no significant effect. Firing rate change after SKF38393was indistinguishable from the spontaneous recovery (Fig. 2A,B).In the remaining two cells, SKF38393 (10 mg/kg, n = 1; 20 mg/kg,n = 1) produced a clear further inhibition (>10% of baseline).When the nine cells were combined, the firing rate was decreasedfrom 56.5 ± 7.3% of baseline immediately before SKF38393 to 52.8± 9.4% at the maximum effect of SKF38393 (Fig. 2A). This changewas statistically not significant (n = 9; p = 0.757, paired ttest).
Fig. 2. Systemic activation of D1-like receptors produces no consistent effect on the activity of SN DA cells in rats pretreated withlow doses of a D2 agonist. A, Graph showing lack of a consistenteffect of the D1 agonist SKF38393 on SN DA cells in rats pretreatedwith low doses of the D2 agonist quinpirole (5-20 µg/kg, i.v.).Open and filled circles represent, respectively, the firing rateof individual cells immediately before SKF38393 administration(10-20 mg/kg, i.v.) and after SKF38393 had produced a maximumeffect. Straight lines link the data from individual cells. Ofnine cells tested, seven were slightly excited or showed no responseto SKF38393 (<10% change in baseline) and two were inhibited.Overall, the firing rate was decreased nonsignificantly from 56.5± 7.3 to 52.8 ± 9.4% of baseline (p = 0.757; n = 9; open and filedbars). B, Typical rate histogram showing lack of an effect ofSKF38393 on the activity of an SN DA cell pretreated with a lowdose of quinpirole. A single dose of quinpirole (QUIN, 10 µg/kg,i.v.) inhibited the firing of the cell to ~40% of baseline. Subsequentadministration of SKF38393 (SKF, 10 mg/kg, i.v.) did not significantlyaffect the remaining activity. In this and following figures,arrows indicate the times of drug injection, and the numbers abovethe arrows represent the doses of the drug injected.
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However, it is possible that a D1 effect depends on activation of D2-like receptors located on DA target neurons rather thanD2 autoreceptors. DA neurons are known to be more sensitive thanDA target neurons to systemically administered DA agonists (Skirbollet al., 1979; White and Wang, 1986; Piercey et al., 1996a). Thedoses of quinpirole used in the above experiments may have beentoo low to activate D2-like receptors significantly on DA targetneurons. To test this possibility, high doses of quinpirole wereadministered to 10 rats. To avoid a complete inhibition, dosesof quinpirole were injected slowly at 3-10 min intervals (seeFig. 3B). Perhaps because of the development of tachyphalaxisof autoreceptors (Aghajanian and Bunney, 1973; Piercey et al.,1996a), DA cells remained active after a slow injection of 40-160(92 ± 15.8) µg/kg. In 9 of 10 cells, subsequent injection of SKF38393(5 mg/kg, n = 1; 10 mg/kg, n = 6; 20 mg/kg, n = 2) produced aclear further inhibition (>10% of baseline; Fig. 3A,B). In theremaining one cell, SKF38393 (20 mg/kg) produced no significanteffect. Overall, the firing rate was decreased by SKF38393 from39.3 ± 4.7 to 10.9 ± 4.1% of baseline (p < 0.0001; n = 10; pairedt test; Fig. 3A,B). Unlike the inhibition induced by quinpirolealone, which was not affected at all by SCH23390 (160 µg/kg; n= 5; Fig. 3C), the inhibition induced by SKF38393 was completelyreversed by SCH23390 (20-80 µg/kg; n = 6; Fig. 3B), confirmingthat it was a D1 effect.
Fig. 3. Systemic activation of D1-like receptors consistently inhibits SN DA neurons in rats pretreated with high doses of a D2 agonist.A, Graph showing the inhibition of DA cells by the D1 agonistSKF38393 (5-20 mg/kg, i.v.) in rats pretreated with high dosesof the D2 agonist quinpirole (40-160 µg/kg, i.v.). Open and filledcircles represent the firing rate of individual cells before andafter SKF38393 injection, respectively. Of 10 cells tested, ninewere inhibited, and one showed no response to SKF38393. On average,the firing rate was significantly decreased from 39.3 ± 4.7 to10.9 ± 4.1% of baseline (p < 0.0001; n = 10; open and filled bars).B, Typical rate histogram showing the inhibition by SKF38393 ofa SN DA cell pretreated with a high dose of quinpirole (QUIN,40 µg/kg). After the final dose of quinpirole, the firing rateof this cell was decreased to about 40% of baseline. Subsequentadministration of SKF38393 (SKF) almost completely stopped theremaining activity. The selective D1 antagonist SCH23390 (SCH)reversed the inhibition induced by SKF38393. Haloperidol (HAL)further increased the firing rate to the predrug level. C, Typicalrate histogram showing lack of an effect of the D1 antagonistSCH23390 on the inhibition induced by the D2 agonist quinpirolealone. After a cumulative dose of 80 µg/kg, quinpirole (QUIN)completely inhibited the activity of this cell. About 2 min later,the cell began to recover spontaneously. SCH23390 (SCH), up to160 µg/kg, produced no effect on the recovery of the cell. Haloperidol(HAL), on the other hand, increased the activity to baseline.
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To rule out the possibility that the slow speed of injection may play a role in the above observed enabling effect of quinpirole,a low dose of quinpirole (10 µg/kg) was administered slowly tofive rats. In four of the five cells examined, SKF38393 (10 mg/kg)produced either no effect (n = 2) or a small increase in firingrate (n = 2; 12.9 and 13.9% of baseline, respectively). In onecell, SKF38393 inhibited the firing by 19% of baseline. Overall,the firing rate was not significantly changed (from 66.2 ± 0.5to 66.7 ± 0.1% of baseline; n = 5; p = 0.93, paired t test), suggestingthat it is the high dose rather than the slow speed of injectionof quinpirole that enables the D1 agonist to inhibit DA cells.

Effect of blockade of D2 autoreceptors on the D1 inhibition of DA neurons
To test more directly the idea that the expression of the D1 effect does not require co-activation of DA autoreceptors, raclopride(2-8 µg), a selective D2 antagonist, was locally applied to theSN 15 min before beginning recordings. In these locally treatedcells, large doses of quinpirole (40 µg/kg, n = 6; 160 µg/kg,n = 11; 640 µg/kg, n = 1) could be injected within a short periodwithout completely inhibiting the cell. On average, the firingrate was inhibited by 47.9 ± 5.1%. In 17 of 18 cells tested, SKF38393(5 mg/kg, n = 3; 7.5 mg/kg, n = 1; 10 mg/kg, n = 13; 20 mg/kg,n = 1) after quinpirole produced a clear further inhibition offiring (>10% of baseline; Fig. 4A,B). In the remaining one cell,the firing rate was reduced by 5%. Overall, SKF38393 significantlydecreased the firing rate from 47.9 ± 5.1 to 16.1 ± 5.1% of baseline(n = 18; p < 0.0001, paired t test; Fig. 4A).
Fig. 4. D1-mediated feedback inhibition persists after DA autoreceptors are blocked. A, Graph showing inhibition by the D1 agonistSKF38393 of DA cells with blocked DA autoreceptors. Before testingfor the D1 response, raclopride was introduced locally just abovethe SN (2-8 µg) to block DA autoreceptors, and high doses of quinpirole(40-640 µg/kg, i.v.) were administered to activate D2-like receptorson DA target neurons. Open and filled circles represent the firingrate of individual cells before and after SKF38393 injection (5-10mg/kg, i.v.), respectively. In 17 of 18 cells, SKF38393 produceda clear further inhibition. On average, the firing rate was reducedsignificantly from 47.9 ± 5.1 to 16.1 ± 5.1% of baseline (openand filled bars; p < 0.0001; n = 18). B, Typical rate histogramshowing the inhibition by SKF38393 of an SN DA cell treated locallywith raclopride (8 µg). A cumulative dose of 40 µg/kg of quinpirole(QUIN) produced a 50% inhibition of firing. Injection of SKF38393(SKF) produced a clear further inhibition. The D1 antagonist SCH39166(SCH) reversed the inhibition induced by SKF38393. The D2 antagonistraclopride (Rac) brought the activity back to baseline.
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Similar experiments were performed in seven other locally raclopride-treated (4-10 µg) DA cells, in which SKF38393 was replacedwith DHX (0.5 mg/kg, n = 3; 0.75 mg/kg, n = 1; 1 mg/kg, n = 3).After pretreatment with quinpirole (160 µg/kg), DHX produced aclear inhibition in all seven cells (from 45.0 ± 7.0 to 13.8 ±4.1% of baseline; p < 0.001, paired t test; Fig. 5).
Fig. 5. The new D1 agonist DHX mimics the effect of SKF38393 and inhibits the activity of DA cells treated with high doses of theD2 agonist quinpirole. A, Graph showing the inhibition inducedby DHX (0.5-1 mg/kg) of seven SN DA cells in rats pretreated withraclopride (4-10 µg, locally in the SN) and with quinpirole (160µg/kg, i.v.). Open and filled circles represent the firing rateof individual cells before and after DHX injection, respectively.All cells showed an inhibitory response to DHX. On average, thefiring rate was reduced from 45.0 ± 7.0 to 13.8 ± 4.1% of baseline(open and filled bars; p < 0.001). B, Typical rate histogram showingthe inhibition by DHX of an SN DA cell pretreated locally withraclopride (10 µg). Quinpirole (QUIN, 160 µg/kg) inhibited thefiring rate of this cell to 65% of baseline. DHX further inhibitedthe activity to 35%. SCH39166 (SCH) reversed the inhibition inducedby DHX. Raclopride further returned the activity to predrug baseline(data not shown).
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Effect of chloral hydrate on D1-mediated inhibition of DA neurons
Some D1-mediated effects have been shown to be blocked by the commonly used anesthetic chloral hydrate (Huang and Walters,1992; Kreiss et al., 1996). To determine whether the D1 inhibitionobserved in the present study shares a similar property, the effectof SKF38393 was reexamined in animals treated with chloral hydrate.Seven animals were anesthetized with chloral hydrate (400 mg/kg,i.p.). To be sure that transection did not affect the result,four of the animals also had their brainstems transected. Becauseanimals in the latter group did not breathe spontaneously, artificialrespiration was performed. The respiration rate was adjusted tomaintain an expired CO₂ level of 3.5-4.5% as measured by a CO₂analyzer. No difference was found between the results obtainedfrom the two groups. Thus, in all animals treated with chloralhydrate, pretreatment with quinpirole (40 µg/kg, n = 3; 80 µg/kg,n = 3; 160 µg/kg, n = 1, injected slowly as described above; seeFig. 3B) failed to enable SKF38393 (10-20 mg/kg) to produce anyfurther inhibition (Fig. 6).
Fig. 6. The anesthetic chloral hydrate blocks the D1-mediated feedback inhibition of SN DA neurons. A, Graph showing lack of an effectof a D1 agonist on SN DA cells in chloral hydrate-anesthetizedanimals (400 mg/kg, i.p.). Before testing for the effect of SKF38393,rats were pretreated with a high dose of quinpirole (40-160 µg/kg,i.v.). Open and filled circles represent the firing rate of individualcells before and after SKF38393 injection (10-20 mg/kg, i.v.),respectively. No significant D1 effect was observed in any ofthe seven cells tested. The average firing rate of the cells wasslightly increased from 33.7 ± 4.0 to 35.8 ± 4.0% of baselineafter SKF38393 injection (open and filled bars; p = 0.082). B,Typical rate histogram showing lack of an effect of SKF38393 (20mg/kg) on an SN DA cell in a chloral hydrate-anesthetized animal(400 mg/kg, i.p.). The firing rate of the cell was reduced toabout 30% of baseline after a high dose of quinpirole (QUIN, 80µg/kg, i.v.). Subsequent administration of SKF38393 (SKF) andSCH23390 (SCH) produced no effect on the remaining activity. Haloperidol(HAL) returned the firing rate to baseline.
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DISCUSSION
The present study suggests that feedback control of DA neurons involves not only D2- but also D1-like receptors. However,the D1-mediated feedback inhibition requires co-activation ofD2-like receptors to be expressed and is blocked completely bya commonly used anesthetic, chloral hydrate.

D1 agonists alone produce variable or no effects on the spontaneous activity of DA neurons
Consistent with a previous study in a locally anesthetized, paralyzed preparation (Carlson et al., 1987), our study showsthat systemically administered SKF38393 produces variable effectson SN DA neurons. However, two other similar studies showed noeffect of SKF38393 on SN DA cells (Huang and Walters, 1992; Sunet al., 1993). The cause for the discrepancy in findings is unknown.However, if SKF38393 alone has an effect, the effect may not bemediated by D1-like receptors. The present study shows that theeffect induced by SKF38393 alone was not reversed by the D1 antagonistSCH23390 in most cells examined and not mimicked by the full D1agonist DHX.

In chloral hydrate-anesthetized animals, SKF38393 was reported to have no effect on the firing rate of DA cells. However,it modulates the D2 response (Kelland et al., 1988). In controlanimals, the ability of the D2 agonist quinpirole to inhibit DAcells is negatively correlated with their basal firing rate. Pretreatmentwith SKF38393 eliminated the rate dependency of the D2 inhibition,suggesting a modulatory role of the D1 feedback pathway. However,as will be discussed, the D1 pathway, under certain conditions,also has an inhibitory effect on DA neurons.

Co-activation of D2-like receptors enables a D1 agonist to inhibit DA neurons
It is well known that the expression of some DA effects requires co-activation of D1- and D2-like receptors (Walters et al.,1987; White, 1987; Bordi and Meller, 1989; Wachtel et al., 1989;Bertorello et al., 1990). The present study suggests that a similarD1-D2 interdependency is involved in feedback control of DA neurons.Our data showed that the D1 agonists SKF38393 and DHX, althoughhaving no effect or producing a variable response in control animals,consistently inhibited DA cells in animals pretreated with highdoses of the D2 agonist quinpirole.

The proposed D1-D2 interaction may also explain why a D1 agonist is capable of inhibiting DA neurons in reserpine-treatedanimals (Huang and Walters, 1992; Sun et al., 1993). Chronic treatmentwith reserpine is known to cause a breakdown of D1-D2 interdependency.As a result, activation of either receptor alone can produce aneffect that, otherwise, can only be observed when both D1- andD2-like receptors are activated (e.g., Arnt, 1985; LaHoste etal., 1996). Although the underlying mechanism for this actionof reserpine remains unclear, it is possible that reserpine treatmentalso interrupts D1-D2 interaction in feedback control of DA cellsso that a D1 agonist alone can produce an inhibition of DA cells(Huang and Walters, 1992; Sun et al., 1993).

D1-mediated feedback inhibition requires co-activation of D2-like receptors on DA target neurons, rather than DA neurons themselves
D2-like receptors are present on both DA neurons (DA autoreceptors) and DA target neurons. Both receptors could be activatedby systemically administered quinpirole, and both may play a rolein enabling the D1 effect. Our results suggest, however, thatthe D1-mediated feedback inhibition does not require activationof DA autoreceptors. In the initial experiments, animals werepretreated with only low doses of quinpirole ( $<=$ 20 µg/kg). Althoughquinpirole produced a significant inhibition in these experiments,no further effect of SKF38393 was observed. Because a low doseof a D2 agonist acts preferentially on DA neurons (Skirboll etal., 1979; White and Wang, 1986; Piercey et al., 1996a), theseresults provided the first evidence suggesting that the expressionof the D1 effect may not depend on activation of DA autoreceptors.In the second set of experiments, animals were pretreated withhigh doses of quinpirole. However, quinpirole had to be injectedslowly to avoid a complete inhibition of DA cells. Although SKF38393produced a clear inhibition in these cells, it was difficult todetermine whether it was the dose of quinpirole injected, thespeed of injection, or the degree of inhibition induced by highdoses of quinpirole that modified the response of the cell toa D1 agonist. To rule out the possibility that the slow injectionmay play a role, animals were given, slowly, a low dose of quinpirole(10 µg/kg). In four of five cells tested, SKF38393 failed to producea clear effect, suggesting that the kinetics of injection of quinpiroleis not a critical factor in the emergence of the D1 effect. Totest more directly whether activation of DA autoreceptors is neededfor the expression of D1 inhibition, raclopride was applied locallyto the SN to block DA autoreceptors. In these experiments, DAcells remained active even after a fast injection of a large doseof quinpirole. Although the degree of inhibition induced by quinpirolewas less compared with that seen in the second set of experiments,SKF38393 produced an even greater inhibition (see Figs. 3, 4).Thus, neither the speed of quinpirole injection nor the degreeof inhibition induced by quinpirole seems to play a role in theobserved D1 inhibition. By demonstrating a D1 effect even afterautoreceptors were blocked, this last set of experiments providedmore direct evidence suggesting that D2-like receptors on DA targetneurons are more important in determining the expression of theD1 feedback inhibition.

Clearly, further experiments are needed to pinpoint where exactly D1 and D2 agonists may interact to regulate the activityof DA cells. With the data available, particularly from anatomicalstudies (see the introductory remarks), one may speculate thatstriatonigral GABA neurons may play a key role. D1-like receptorsare found on both their cell bodies in the striatum and theirterminals in the SN. An in vitro study showed that activationof D1-like receptors on GABAergic terminals in the ventral tegmentalarea increases GABA_B receptor-mediated GABA input to DA neurons(Cameron and Williams, 1993). Whether this is also the case inthe SN has not been determined. An in vivo study in reserpinizedanimals suggests, however, that systemically administered SKF38393may act mainly in the striatum to inhibit DA neurons (Sun et al.,1996).

A D2 agonist may act directly on the same striatonigral neurons to modulate the D1 effect, if D1- and D2-like receptors co-localizein these cells (Lester et al., 1993; Surmeier et al., 1993, 1996).Alternatively, D2 agonists may act on a different population ofstriatal or nonstriatal neurons to modulate D1-mediated feedbackpathways indirectly. Previously, systemic administration of theD2 agonist quinpirole was shown to increase the activity of somestriatal neurons (at doses higher than those needed to inhibitDA cells; Piercey et al., 1996b). The D1 agonist SKF38393 alone,on the other hand, produced only a small or no effect (Pierceyet al., 1996b). Although it is unclear how the D2 excitatory effectis produced, a recent in vitro study suggests that during D2-inducedexcitation, a D1 agonist may become capable of further increasingthe activity of striatal neurons (Hernandezlopez et al., 1997).If, under such conditions, striatonigral neurons are among thecells that are further excited by the D1 agonist, this D1-mediatedexcitation in the striatum would be translated into an inhibitionof nigral DA neurons. Further experiments are needed to determinewhether this hypothesis is correct.

Clinical speculations
The involvement of both D1- and D2-like receptors in feedback control of DA neurons could have significant clinical implicationsif drugs selective for DA receptor subtypes were used for treatingdisorders such as schizophrenia, Parkinson's disease, and substanceabuse. Because of the presence of feedback pathways, these drugsmay produce unexpected results. For example, a D2-selective agonistmay be used for treating Parkinson's disease. However, at lowdoses, D2 agonists may act preferentially on D2 autoreceptorsto inhibit the activity of the remaining DA cells and their releaseand, thus, exacerbate the symptoms. Although at high doses a D2agonist may act postsynaptically to increase D2 receptor-mediatedfunction, the residual D1 function, mediated by endogenously releasedDA, may become further reduced because of the D2-mediated feedbackinhibition. Our data suggest that a D1 agonist may lead to a similarreduction in the availability of endogenous DA for action at D2-likereceptors.

Most antipsychotic drugs are D2 antagonists. These drugs are known to block feedback inhibition and to increase DA cell activityand DA release. If an antipsychotic drug blocks only D2 receptors,the increased DA release would lead to a selective stimulationof D1 receptors. Similarly, a selective D1 antagonist may increasethe availability of endogenous DA for action at D2-like receptors.Although remaining to be verified, the proposed feedback pathway-mediatedeffects may contribute to the clinical effects of current drugsacting on DA systems.

FOOTNOTES

Received April 21, 1997; revised July 22, 1997; accepted July 30, 1997.

This work was supported in part by the Schizophrenia Research Program of the Scottish Rite Benevolent Foundation (W-X.S.),a NASARD Young Investigator Award (W.-X.S.), the Stanley Foundationfor Research on the Mentally Ill (B.S.B), United States PublicHealth Service Grants MH52686 (W.-X.S.) and MH28849 (B.S.B), andthe State of Connecticut. We thank Interneuron Pharmaceuticals,Schering-Plough, Astra, Eli Lilly, and McNeil Pharmaceuticalsfor their generous supply of DHX, SCH39166, raclopride, quinpirole,and haloperidol, respectively.

Correspondence should be addressed to Dr. Wei-Xing Shi, Department of Psychiatry, Yale University School of Medicine, 333Cedar Street, SHM B-272, New Haven, CT 06510.

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