Distinct Roles for Nigral GABA and Glutamate Receptors in the Regulation of Dendritic Dopamine Release under Normal Conditions and in Response to Systemic Haloperidol

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The Journal of Neuroscience, February 15, 2002, 22(4):1407-1413

Distinct Roles for Nigral GABA and Glutamate Receptors in the Regulation of Dendritic Dopamine Release under Normal Conditions and in Response to Systemic Haloperidol
William S. Cobb and Elizabeth D. Abercrombie
Center for Molecular and Behavioral Neuroscience, Rutgers University, Newark, New Jersey 07102

  ABSTRACT

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The regulation of dendritic dopamine release in the substantia nigra (SN) likely involves multiple mechanisms. GABA and glutamateinputs to nigrostriatal dopamine neurons exert powerful influenceson dopamine neuron physiology; therefore, it is probable thatGABA and glutamate likewise influence dendritic dopamine release,at least under some conditions. The present studies used in vivomicrodialysis to determine the potential roles of nigral GABAand glutamate receptors in the regulation of dendritic dopaminerelease under normal conditions and when dopamine signaling inthe basal ganglia is compromised after systemic haloperidol administration.Nigral application of the GABA_A receptor antagonist bicucullineby reverse dialysis significantly increased spontaneous dopamineefflux in the SN. However, spontaneous dopamine efflux in theSN was not significantly affected by local application of theglutamate receptor antagonists 6-cyano-7-nitroquinoxaline-2,3-dioneor (±)-3-[2-carboxypiperazine-4-yl]-propyl-1-phosphonic acid.Systemic haloperidol administration significantly increased theextracellular dopamine measured in the SN. Blockade of nigralGABA_A receptors by local bicuculline application did not alterthis effect of systemic haloperidol, despite the bicuculline-inducedincrease in spontaneous dendritic dopamine efflux. In contrast,nigral application of either glutamate receptor antagonist significantlyattenuated the increases in dendritic dopamine efflux elicitedby systemic haloperidol. These data suggest that under normalconditions, activity of GABA afferents to SN dopamine neuronsis an important determinant of the spontaneous level of dendriticdopamine release. Circuit-level changes in the basal ganglia involvingan increased glutamatergic drive to the SN appear to underliethe increase in dendritic dopamine release that occurs in responseto systemic haloperidoladministration.

Key words: basal ganglia; dendritic dopamine release; microdialysis; Parkinson's disease; substantia nigra; subthalamic nucleus

  INTRODUCTION

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Nigrostriatal dopamine neurons release dopamine similarly from axon terminals and somatodendritic regions (Geffen et al.,1976; Paden et al., 1976; Wilson et al., 1977; Heeringa and Abercrombie,1995). Dendritic dopamine release is probably regulated by dopamineneuron electrical activity (Rice et al., 1997; Jaffe et al., 1998),which importantly depends on the influence of GABA- and glutamate-containingafferents (Scarnati and Pacitti, 1982; Johnson et al., 1992; Smithand Grace, 1992; Chergui et al., 1994; Tepper et al., 1995; Iribeet al., 1999; Paladini et al., 1999). Therefore, the activitystate of GABA and glutamate afferent inputs influences somatodendriticdopamine release; moreover, such regulation may differ dependingon the relative state of basal gangliafunctioning.

Dopamine neurons are densely innervated by inhibitory GABAergic afferents (Nitsch and Riesenberg, 1988; Bolam and Smith, 1990;Tepper et al., 1995) and also receive excitatory glutamatergicinputs (Jackson and Crossman, 1983; Kita and Kitai, 1987; Naitoand Kita, 1994). Nigral application of GABAergic antagonists increasesthe extracellular dopamine recovered in the striatum and substantianigra (SN) (Westerink et al., 1992b), suggesting that endogenousGABAergic tone in the SN maintains a powerful inhibitory influenceover spontaneous dopamine release from nerve terminals and dendrites.Stimulation of nigral glutamatergic afferents to the SN or nigralapplication of glutamate agonists increases striatal and nigraldopamine efflux (Mintz et al., 1986; Araneda and Bustos, 1989;Westerink et al., 1992a,b; Rosales et al., 1994). Thus, glutamatergicinput to dopamine neurons can stimulate dendritic dopamine releaseand, like GABA, glutamate can regulate nerve terminal and dendriticdopamine release. Whether a tonic glutamate influence participatesin the regulation of spontaneous dendritic dopamine release, however,has yet to bedetermined.

Examining the relative contributions of GABA and glutamate afferents to the SN in relation to evoked changes in dendriticdopamine release may add additional insight into the relativeinvolvement of these inputs in the regulation of this processunder normal versus pathological conditions. Dopamine loss withinthe basal ganglia in Parkinson's disease is thought to resultin an increased role for afferent control of the SN by glutamateas well as a diminution of the concomitant influence of nigralGABAergic inputs (Miller and DeLong, 1987; Bergman et al., 1990;Robledo and Feger, 1991; Bergman et al., 1994; Kreiss et al.,1996). Systemic haloperidol administration produces an acute drug-inducedparkinsonian state and increases somatodendritic dopamine efflux(Abercrombie et al., 1998; Bradley et al., 2000). Furthermore,catalepsy produced by haloperidol administration is disruptedby glutamate receptor antagonist application into the subthalamicnucleus (STN). The latter provides glutamatergic input to theSN and is known to be hyperactive in parkinsonism (see above)(Miller and DeLong, 1987; Miwa et al., 1998b). Interestingly,intracerebroventricular application of the glutamate antagonistkynurenate abolishes increases in dopamine neuron firing rateproduced by systemic haloperidol (Tung et al., 1991).

The aim of this study was to investigate potential differences in the relative roles of nigral GABA and glutamate afferentsin the regulation of spontaneous dendritic dopamine release comparedwith evoked dendritic dopamine release produced by systemic haloperidoladministration.

  MATERIALS AND METHODS

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Animals. Adult male Sprague Dawley rats (Zivic-Miller Laboratories, Pittsburgh, PA) were used in all experiments. Animalswere housed individually in plastic shoebox cages and suppliedwith food and water ad libitum. Animals were kept under conditionsof constant temperature (21°C) and humidity (40%) and maintainedon a 12 hr light/dark cycle. Rats weighed between 275 and 325g at the time of each experiment. All efforts were made to minimizeanimal suffering and to limit the number of animals used for theseexperiments. Animal procedures were conducted in accordance withthe National Institutes of Health Guide for the Care and Use ofLaboratory Animals (revised 1985), and all protocols were approvedby the Rutgers University Institutional Animal Care and UseCommittee.

Microdialysis probe construction and implantation. Microdialysis probes were of the vertical concentric design adapted frompreviously described methods (Abercrombie and Finlay, 1991). Polyethylenetubing (PE-10 tubing; Clay Adams, Parsippany, NJ) served as theinlet to the probe, and fused silica capillary tubing (PolymicroTechnologies, Phoenix, AZ) served as the outlet. The silica tubingwas inserted through the wall and into the lumen of the PE-10tubing such that it extended 10 mm past the tubing tip. A semipermeablemicrodialysis membrane (molecular weight cutoff = 6000; outerdiameter = 200 µm; Spectrum Laboratories, Rancho Dominguez, CA)was placed over the end of the exposed silica tubing, and thetip of the membrane was plugged with epoxy. The silica tubingwas fixed into position with epoxy, and the exposed portion ofthe dialysis membrane was coated with a thin epoxy layer, leavinga 1.5 mm long active exchange area at the end of the probe. Themicrodialysis probes were continuously perfused with artificialCSF solution (in mM: 147 NaCl, 2.5 KCl, 1.3 CaCl₂, 0.9 MgCl₂,pH $approx$ 7.4) at a rate of 1.5 µl/min with a syringe pump (HarvardApparatus, Holliston,MA).

Before implantation, probes were calibrated to determine relative in vitro recovery rates to exclude dysfunctional microdialysisprobes. Probes were considered dysfunctional if recovery was notwithin the range of 10-15% relative recovery. Animals were anesthetizedwith chloral hydrate (400 mg/kg, i.p.) or sodium pentobarbital(50 mg/kg, i.p.) and mounted into a stereotaxic device (DavidKopf Instruments, Tujunga, CA). Probes were set at a 30° lateralangle and implanted into the SN at the following coordinates:anteroposterior, $-$ 5.1 mm; mediolateral, ±5.6 mm relative to bregma;and dorsoventral, $-$ 8.0 mm below dura (Paxinos and Watson, 1986;Heeringa and Abercrombie, 1995). The probe assembly was fixedto the skull with fast-curing dental cement and three skull screws.The inlet of the probe was connected to a single-channel fluidswivel (Instech Laboratories, Inc., Plymouth Meeting, PA), thusallowing the animal to move freely. Experiments were conductedat least 18 hr after probeimplantation.

Analysis of dialysate. Dialysis samples (20 µl) were collected every 15 min and analyzed for dopamine content by HPLC coupledwith electrochemical detection. A Velosep RP-18 column (100 ×3.2 mm; Applied Biosystems, Inc., Foster City, CA) was used, andthe mobile phase was composed of 0.1 M sodium acetate buffer,pH 4.1, 0.1 mM EDTA, 1.2 mM sodium octyl sulfate, and 6.5% (v/v)methanol. An electrochemical detector (Waters model 460; MilliporeCorp., Bedford, MA) with an amperometric electrode set at an appliedpotential of +0.6 V was used. A solvent delivery pump (model LC-10AD;Shimadzu Corp., Columbia, MD) delivered the mobile phase at aflow rate of 0.7 ml/min. The system was calibrated daily with20 µl of 10 nM standard solution in 0.1 M perchloric acid. Retentiontime was used to identify dopamine, which was quantified on thebasis of peak height. The limit of detection for dopamine in thisanalysis was ~0.3pg.

Experimental manipulations. Haloperidol was dissolved in ~40 µl of glacial acetic acid, diluted (0.5 mg/ml) in 0.9% salinesolution (v/v), and administered via intraperitoneal injectionat a dose of 0.5 mg/kg. In all experiments, at least three consecutivemicrodialysis samples were collected before drug administrationto establish baseline values for spontaneous dopamine efflux (variabilityof <10%). In experiments involving local application of bicucullinemethchloride, 6-cyano-7-nitroquinoxaline-2,3-dione (CNQX), or(±)-3-[2-carboxypiperazine-4-yl]-propyl-1-phosphonic acid (CPP)by reverse dialysis, the drug was diluted in the artificial CSFperfusate solution (CNQX and bicuculline, 100 µM; CPP, 50 µM.)The applied concentrations of CNQX and CPP were chosen on thebasis of previous studies demonstrating effective antagonism ofevoked increases in striatal dopamine efflux produced by kainateand NMDA, respectively (Keefe et al., 1992). In all interactionexperiments, antagonists were continuously applied locally viathe probe beginning 90 min before systemic haloperidol administrationto allow sufficient time to achieve a new stablebaseline.

Data analysis. Data are expressed as mean ± SEM. Values represent picograms of dopamine per 20 µl microdialysis sample. Dialysatevalues are not corrected for in vitro probe recovery. To examinethe effect of drug treatments on extracellular dopamine recovery,postdrug samples were compared with the average baseline, andwithin-group effects were analyzed using a one-way ANOVA withrepeated measures over time coupled to Dunn's post hoc test (p< 0.05). Between-group differences were assessed by a two-wayANOVA with repeated measures over time (p < 0.05).

Histology. After completion of each experiment, the animal was given a lethal dose of sodium pentobarbital and perfused transcardiallywith buffered formalin (10%); the brain was then removed. Coronalslices of 50 µm thickness were stained with cresyl violet to verifyplacement of microdialysis probes within the SN (Fig. 1). Onlydata from experiments with probe placement within the region ofthe SN ventral to the pars compacta were included in the dataanalyses.

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Figure 1. A, Cresyl violet-stained coronal section at the level of the midbrain showing microdialysis probe localization within the SN. The arrow denotes the probe track. SNc, Substantia nigra pars compacta; SNr, substantia nigra pars reticulata. B, Chromatogram obtained from a 20 µl dialysate sample under baseline conditions. The dopamine (DA) peak observed in this chromatogram is equal to 1.0 pg.

Materials. Chloral hydrate, sodium pentobarbital, haloperidol, CNQX, CPP, and bicuculline methchloride were purchased fromSigma (St. Louis, MO). All other reagents and chemicals were ofthe highest purity commercially available (Fischer Scientific,Springfield,NJ).

  RESULTS

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Effect of local application of GABA or glutamate receptor antagonists on extracellular dopamine in the SN

Local perfusion with the GABA_A receptor antagonist bicuculline (100 µM) significantly increased dopamine release in the SNfrom a baseline level of 0.9 ± 0.1 pg/sample to an overall absolutepeak level of 2.6 ± 0.2 pg/sample (F_(10,60) = 30.5; p < 0.01;n = 7) (Fig. 2). This manipulation produced increased behavioralactivation and contralateral turning in most animals lasting forthe duration of bicuculline application in the SN. Local perfusionwith the non-NMDA glutamate receptor antagonist CNQX (100 µM)did not significantly alter the extracellular dopamine level inthe SN (F_(6,30) = 0.83; p = 0.56; n = 6) (Fig. 2). Reverse dialysiswith the NMDA glutamate receptor antagonist CPP (50 µM) also didnot significantly alter spontaneous dopamine efflux in the SN(F_(6,42) = 1.38; p = 0.24; n = 8) (Fig. 2). No noticeable behavioraleffect was observed with the application of either glutamate receptorantagonist.

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Figure 2. Extracellular dopamine levels after reverse dialysis application of bicuculline, CNQX, and CPP. Bicuculline significantly increased spontaneous dopamine efflux in the SN (n = 7). Local application of CNQX (n = 6) or CPP (n = 8) had no effect on basal levels of extracellular dopamine in the SN. The horizontal bar denotes local drug application by reverse dialysis. All data are mean ± SEM; *p < 0.05.

Effect of local application of GABA or glutamate receptor antagonists on increases in extracellular dopamine in the SN produced by intraperitoneal haloperidol

Systemic administration of the mixed D₂/D₁ dopamine receptor antagonist haloperidol (0.5 mg/kg) significantly increased extracellulardopamine in the SN from 1.1 ± 0.1 pg/sample to an overall absolutepeak level of 1.7 ± 0.2 pg/sample (F_(10,60) = 4.16; p < 0.01;n = 7) (Fig. 3). This effect was observed in the first postdrugsample and was at least 2.5 hr in duration. Animals displayedmarkedly decreased levels of behavioral activation for the durationof the experiment.

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Figure 3. Extracellular dopamine after systemic administration of haloperidol (HAL). Systemic administration of haloperidol (0.5 mg/kg, i.p.; arrow) produced a significant increase in extracellular dopamine within the SN (n = 7). All data are mean ± SEM; *p < 0.05.

In separate groups of animals, GABA or glutamate receptor antagonists were applied into the SN via the microdialysis probe,and the effect on haloperidol-induced increases in dendritic dopamineefflux was investigated. Intranigral application of bicuculline(100 µM) caused an increase in extracellular dopamine in the SNthat reached a plateau 90 min after application and was sustainedat this new level (Fig. 4A). Based on this observation, intraperitonealadministration of haloperidol was performed 90 min after onsetof local drug application in the present experiments.

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Figure 4. A, Systemic administration of haloperidol (HAL) significantly increased extracellular dopamine in the SN in the presence of local bicuculline (BIC). After the maximum effect of reverse application of bicuculline (horizontal bar) was reached, subsequent systemic administration of haloperidol (0.5 mg/kg; arrow) significantly increased extracellular dopamine in the SN compared with the sample immediately preceding systemic administration of haloperidol (n = 8). Moreover, a significant interaction existed between the increase in nigral dopamine recovery produced by systemic administration of haloperidol in the presence of local bicuculline and that produced by bicuculline alone (n = 7). B, The absolute dopamine increase measured after systemic administration of haloperidol in the presence of intranigral bicuculline compared with haloperidol alone under control conditions (Fig. 3). Values were calculated by subtracting postdrug values from the average of the two baselines immediately before systemic administration of haloperidol in the presence or absence of intranigral bicuculline. All data are mean ± SEM; *p < 0.05.

As observed previously, nigral application of bicuculline (100 µM) elicited an increase in spontaneous dopamine efflux inthe SN from a baseline level of 0.9 ± 0.1 pg/sample to 2.4 ± 0.2pg/sample at 90 min (F_(6,42) = 39.13; p < 0.01; n = 8) (Fig. 4A).Ninety minutes after bicuculline was applied via the probe inthe SN, systemic haloperidol (0.5 mg/kg, i.p.) elicited an additionalsignificant increase in dendritic dopamine release from 2.4 ±0.2 pg/sample to an overall absolute peak level of 2.8 ± 0.3 pg/sample(F_(6,42) = 3.69; p < 0.01; n = 8) (Fig. 4A). A significant interactionwas obtained (F_(5,65) = 3.66; p < 0.01) between the increase inextracellular dopamine in the SN produced by haloperidol in thepresence of bicuculline and the dopamine levels observed withbicuculline alone (n = 7). A direct comparison of the absoluteincrease in nigral dopamine (picograms per sample) elicited bysystemic haloperidol alone or by systemic haloperidol administrationduring local application of bicuculline revealed no significantdifference between the two conditions (F_(4,52) = 4.03; p = 0.40)(Fig. 4B).

Nigral application of CNQX did not affect spontaneous dendritic dopamine release, consistent with previous results (see above).However, local CNQX completely blocked the increased dopamineefflux in the SN produced by systemic haloperidol (F_(10,50) =0.56; p = 0.84; n = 6) (Fig. 5A). Therefore, a significant interactionwas obtained when the effects of systemic haloperidol on extracellulardopamine in the SN in the presence and absence of intranigralCNQX were compared (F_(12,132) = 2.75; p < 0.01). The ability ofsystemic haloperidol to increase dendritic dopamine release alsowas blocked by the presence of CPP in the dialysis perfusate (F_(10,70)= 0.75; p = 0.68; n = 8) (Fig. 5B). Likewise, a significant interactionwas obtained when the effects of systemic haloperidol on extracellulardopamine in the SN in the presence and absence of intranigralCPP were compared (F_(12,156) = 4.65; p < 0.01).

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Figure 5. A, Reverse dialysis with CNQX attenuated the ability of systemic haloperidol (HAL) (0.5 mg/kg; arrow) to significantly increase extracellular dopamine in the SN (n = 6). There was a significant difference between the effect of haloperidol in the presence of CNQX and haloperidol alone. B, Reverse dialysis with CPP blocked the ability of systemic haloperidol (0.5 mg/kg; arrow) to increase extracellular dopamine in the SN (n = 8). There was a significant difference between the effect of haloperidol in the presence of CPP and haloperidol alone. The horizontal black bar denotes local drug application by reverse dialysis. All data are mean ± SEM; *p < 0.05.

  DISCUSSION

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The goal of the present studies was to offer insight into the regulation of dendritic dopamine release in the SN by GABA andglutamate, thus contributing to the present understanding of thefunctioning of basal ganglia circuitry under normal conditionsand under conditions when dopamine neurotransmission is compromised.We first examined the involvement of nigral GABA and glutamatereceptors in the regulation of spontaneous dopamine release inthe SN. In subsequent experiments, we examined the involvementof nigral GABA and glutamate signaling in the increase in dendriticdopamine efflux that was observed to occur in response to intraperitonealadministration ofhaloperidol.

We observed that nigral application of the GABA_A receptor antagonist bicuculline via the microdialysis probe significantlyincreased the extracellular dopamine measured in the SN of unanesthetizedrats. Under the same conditions, local application of either theAMPA/kainate glutamate receptor antagonist CNQX or the NMDA glutamatereceptor antagonist CPP failed to significantly alter spontaneousdopamine efflux in the SN. The increase in dendritic dopaminerelease elicited by nigral bicuculline application suggests thatnigral GABA afferents maintain a strong inhibitory influence ondendritic dopamine release under normal conditions. In contrast,our data suggest that nigral glutamate afferents play a relativelyminor role in the regulation of dendritic dopamine efflux in thissituation. As a result, the level of spontaneous dendritic dopaminerelease normally is determined by activity in GABA afferents ratherthan by glutamatergicneurotransmission.

We found that dendritic dopamine efflux was increased to a similar extent by systemic haloperidol regardless of whether GABA_Areceptors were blocked by nigral application of bicuculline. Thefinding that the increase in the spontaneous efflux of dopaminein the SN produced by local application of bicuculline is additivewith the increase in this variable produced in response to systemichaloperidol administration indicates that separate mechanismsare involved in these two effects. Disinhibition of dendriticdopamine release caused by a net reduction in the activity ofGABA inputs to SN dopamine neurons cannot account for the effectof systemic haloperidol on dendritic dopamine release in the SN,because dopamine continues to increase after systemic administrationof haloperidol in the presence of local bicuculline. An alternativemechanism such as increased glutamate drive to the SN and/or anemergent autoreceptor effect is likely to explain the haloperidol-inducedincreases in dendritic dopamine release observed under these conditions.We observed that nigral application of the glutamate receptorantagonist CNQX or CPP did effectively prevent haloperidol-inducedincreases in dendritic dopamine efflux. Thus, we infer from theseresults that increased glutamatergic drive to the SN mediatesincreases in dendritic dopamine efflux in response to systemicadministration of haloperidol under these conditions. Moreover,this action of glutamate apparently can be effected via both non-NMDAand NMDA receptor signalingpathways.

The STN is a potential source for increased glutamate drive to the SN in response to systemic haloperidol. Previous work hasshown that activation of the STN elicits an increase in nigraldopamine efflux that is mediated by glutamate (Mintz et al., 1986;Rosales et al., 1994, 1997). Evidence consistent with an activationof the STN in response to systemic haloperidol comes from studiesshowing that systemic haloperidol increases the induction of c-Fosin STN targets, including the SN (Miwa et al., 1998a). Furthermore,intraperitoneal injection of group II metabotropic glutamate receptorantagonists reverses haloperidol-induced catalepsy (Bradley etal., 2000), and postural asymmetries are produced by systemichaloperidol when STN activity is altered unilaterally (Miwa etal., 1998b). Although these studies cite the STN as a potentialsource for the hyperactive glutamatergic drive to dopamine neuronsafter systemic administration of haloperidol, it is noted thatelectrophysiological studies fail to show a consistent net effectof haloperidol on the firing rate of individual STN neurons (Hollermanet al., 1992). Other glutamatergic afferents to the SN, includingthe cortex and pedunculopontine nucleus, also potentially couldcontribute to the stimulation of dendritic dopamine release inresponse to systemic administration of haloperidol, but the mechanismwhereby systemic haloperidol might activate these structures isless clear based on current models of basal ganglia function (Scarnatiet al., 1986; Canteras et al., 1990; Di Loreto et al., 1992; Naitoand Kita, 1994; Futami et al., 1995).

Haloperidol elicits a profound parkinsonian state in humans, and acute administration of haloperidol elicits at least someof the same behavioral and physiological effects that are producedby nigrostriatal dopamine lesion in animals (Ungerstedt and Arbuthnott,1970; Ranje and Ungerstedt, 1977; Ross, 1990; Zimbroff et al.,1997). Therefore, to the extent that systemic haloperidol administrationcan be viewed as acutely modeling the changes that occur in thebasal ganglia circuitry in Parkinson's disease (see the introductoryremarks), the present data further underscore the likelihood thatfunctional changes in the afferent regulation of SN dopamine neuronfunction, by glutamate in particular, may contribute to the diseasephenotype in the early stages of the disorder. It has been suggestedthat an increased influence of glutamatergic input from the STNto the SN is present during the presymptomatic period of Parkinson'sdisease and that this change in afferent regulation of survivingdopamine neurons contributes to the maintenance of dopaminergicfunction in the nigrostriatal system during this period (Bezardet al., 1997, 1999). The present data support this notion as wellas underscore the contribution of dendritic dopamine release inthe SN as an essential component of basal ganglia function (Robertsonand Robertson, 1988, 1989; Timmerman and Abercrombie, 1996; Abercrombieand DeBoer, 1997; Crocker, 1997).

The proposed circuit-based mechanism for the stimulatory action of systemic haloperidol on dendritic dopamine release in theSN is consistent with the hypothesis that relief from autoreceptor-mediatedinhibition plays a minor role in this effect (Starke et al., 1989).In vitro electrochemical studies have shown that electricallystimulated nigral dopamine release is at best weakly influencedby autoinhibition (Cragg and Greenfield, 1997; Hoffman and Gerhardt,1999). Furthermore, significant increases in nigral dopamine effluxare elicited by systemic but not nigral administration of D₂ dopaminereceptor antagonists (Westerink and de Vries, 1989; Westerinket al., 1994; Abercrombie et al., 1998). Therefore, an alterationin the activity of basal ganglia circuitry and resulting changesin afferent glutamate input to the SN, rather than antagonismof local impulse- and release-regulating D₂ autoreceptors on nigrostriataldopamine neurons, best explains the increase in dendritic dopaminerelease observed in response to systemic haloperidol. An apparentlylimited role of nigral autoreceptors in the regulation of dendriticdopamine release contrasts strongly with the incontrovertiblerole of autoregulation in the control of nerve terminal dopaminerelease. Blockade of D₂ autoreceptors in the SN by haloperidolincreases dopamine neuron firing rates (Groves et al., 1975; Pucakand Grace, 1994), and systemic, nigral, or striatal administrationof D₂ antagonists increases dopamine efflux in the striatum (Zetterstromet al., 1984; Westerink and de Vries, 1989; Westerink et al.,1992b). Thus, it appears that local blockade of nigral autoreceptorscan increase the activity of nigrostriatal dopamine neurons andstimulate nerve terminal dopamine release without affecting dendriticdopamine release. This situation adds further credence to theintriguing possibility that dopamine neuron firing rate and dendriticdopamine release may not always be parallel. Compartmentalizationof ionic conductances on membrane regions of the dopamine neuronmight allow for dendritic excitability to be independent of firingrate, so that under certain conditions nerve terminal and dendriticdopamine release can be uncoupled (Nedergaard et al., 1988; Grace,1990; Trent and Tepper, 1991; Tepper et al., 1997).

In summary, nigral dopamine release in the intact basal ganglia appears to be subject to strong regulation by GABA afferentswith little or no apparent influence of glutamate neurotransmission.However, when dopamine neurotransmission in this circuitry isimpaired by systemic haloperidol administration, excitatory effectsof glutamate on dendritic dopamine efflux supersede the tonicinhibition by GABA, and increases in nigral dopamine release occur.Therefore, these results reveal distinct roles for GABA and glutamateafferents to the SN in the regulation of dendritic dopamine releasein these two conditions. Additional investigation into the exactanatomic substrates that underlie these findings will furtherelucidate the afferent regulation of somatodendritic dopaminerelease under normal and pathologicalconditions.

  FOOTNOTES

Received Sept. 7, 2001; revised Nov. 14, 2001; accepted Nov. 25, 2001.

This research was supported by United States Public Health Service Grant NS19608. We thank Dr. David W. Miller and James A.Zackheim for assistance with the data analysis and the manuscript,Dr. James M. Tepper for helpful discussions, and Alma Pangilinanand Mary Antonuccio for technicalassistance.
Correspondence should be addressed to William S. Cobb, 197 University Avenue, Newark, NJ 07102-1814. E-mail: cobb{at}axon.rutgers.edu.

  REFERENCES

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

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