Cholinergic Neuronal Modulation Alters Dopamine D2 Receptor Availability In Vivo by Regulating Receptor Affinity Induced by Facilitated Synaptic Dopamine Turnover: Positron Emission Tomography Studies with Microdialysis in the Conscious Monkey Brain

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The Journal of Neuroscience, September 15, 2000, 20(18):7067-7073

Cholinergic Neuronal Modulation Alters Dopamine D₂ Receptor Availability In Vivo by Regulating Receptor Affinity Induced by Facilitated Synaptic Dopamine Turnover: Positron Emission Tomography Studies with Microdialysis in the Conscious Monkey Brain
Hideo Tsukada, Norihiro Harada, Shingo Nishiyama, Hiroyuki Ohba, and Takeharu Kakiuchi
Central Research Laboratory, Hamamatsu Photonics K. K., Shizuoka 434-8601, Japan

  ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

To evaluate the cholinergic and dopaminergic neuronal interaction in the striatum, the effects of scopolamine, a muscariniccholinergic antagonist, on the striatal dopaminergic system wereevaluated multi-parametrically in the conscious monkey brain usinghigh-resolution positron emission tomography in combination withmicrodialysis. L-3,4-Dihydroxyphenylalanine (L-[ $beta$ -¹¹C]DOPA) and 2 $beta$ -carbomethoxy-3 $beta$ -(4-fluorophenyl)tropane ([ $beta$ -¹¹C]CFT) were used to measure dopamine synthesis rate and dopaminetransporter (DAT) availability, respectively. For assessment ofdopamine D₂ receptor binding in vivo, [¹¹C]raclopride was applied because this labeled compound, whichhas relatively low affinity to dopamine D₂ receptors, was hypothesizedto be sensitive to the striatal synaptic dopamine concentration.Systemic administration of scopolamine at doses of 10 and 100µg/kg dose-dependently increased both dopamine synthesis and DATavailability as measured by L-[ $beta$ -¹¹C]DOPA and [ $beta$ -¹¹C]CFT, respectively. Scopolamine decreased the binding of [¹¹C]raclopride in a dose-dependent manner. Scopolamine induced nosignificant changes in dopamine concentration in the striatalextracellular fluid (ECF) as determined by microdialysis. However,scopolamine dose-dependently facilitated the striatal ECF dopamineinduced by the DAT inhibitor GBR12909 at a dose of 0.5 mg/kg.Scatchard plot analysis in vivo of [¹¹C]raclopride revealed that scopolamine reduced the apparent affinityof dopamine D₂ receptors. These results suggested that the inhibitionof muscarinic cholinergic neuronal activity modulates dopamineturnover in the striatum by simultaneous enhancement of the dynamicsof dopamine synthesis and DAT availability, resulting in no significantchanges in apparent "static" ECF dopamine level but showing adecrease in [¹¹C]raclopride binding in vivo attributable to the reduction ofaffinity of dopamine D₂receptors.

Key words: L-[ $beta$ -¹¹C]DOPA; [¹¹C]raclopride; [ $beta$ -¹¹C]CFT; positron emission tomography; microdialysis; monkey brain

  INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The neurotransmitter systems do not work in isolation, and they are anatomically and functionally integrated as a networkdirectly (Hattori et al., 1976) or indirectly (Bunney and Aghajanian,1976) through multisynaptic connections. Although neuropsychiatricand neurodegenerative diseases have been attributed to deficitswithin a single neurotransmitter system, disease progression mightbe related to the deficit of the initially affected system tomodulate or be modulated by other neurotransmitters. The extrapyramidalmotor system, for example, relies on a balance between dopamineand acetylcholine, and disruption in the balance results in motorabnormalities. Positron emission tomography (PET) can evaluatethe functional responses of neurotransmitters to pharmacologicalmanipulation, as well as the interactions between neuronal systems.PET has been used to assess the effects of endogenous dopamine(Innis et al., 1992; Dewey et al., 1993a; Carson et al., 1997),NMDA/glutamate (Smith et al., 1997), acetylcholine (Dewey et al.,1993b), serotonin (Dewey et al., 1995), and GABA (Dewey et al.,1992) on striatal [¹¹C]raclopride binding (for review, see Laruelle, 2000). These reportssuggested that the changes in striatal synaptic dopamine couldbe measured noninvasively by PET using [¹¹C]raclopride, which has more moderate affinity for D₂ receptorsthan [¹¹C]N-methyl spiperone (NMSP) (Seeman et al., 1989; Young et al.,1991). The measurement is based on the principle that neurotransmittersmight compete with a radiolabeled ligand on the receptors if theaffinity of the ligand to the receptor is moderate. In fact, basicstudies using rodents demonstrated that increases or decreasesin dopamine concentration decreased or increased the in vivo bindingof [³H]/[¹¹C]raclopride, respectively. (Seeman et al., 1989; Inoue et al.,1991; Young et al., 1991; Ginovart et al., 1997). However, wedemonstrated recently that the alternation of [¹¹C]raclopride binding in vivo as measured by PET was not regulatedsimply by the apparent "static" dopamine level in the synapse,i.e., it represents the dynamic balance of release and reuptakerates of dopamine (Tsukada et al., 1999a, 2000a). Thus, in theconscious monkey brains in combination with animal PET and microdialysis,we showed that indirect dopamine modulators such as benztropine(a muscarinic cholinergic antagonist) and ketanserine (a 5-HT₂antagonist) reduced [¹¹C]raclopride binding in the striatum with much smaller degreeof increase in synaptic dopamine than those induced by methamphetamineand GBR12909 (Tsukada et al., 1999a). In addition, ketamine, anoncompetitive NMDA receptor antagonist, reduced [¹¹C]raclopride binding in the striatum without any significant changein the synaptic dopamine concentration (Tsukada et al., 2000a).

The aim of the present study was to explore the regulatory mechanisms between cholinergic and dopaminergic neuronal systemsmulti-parametrically using PET in combination with L-3,4-dihydroxyphenylalanine(L[ $beta$ -¹¹C]DOPA), [¹¹C]raclopride, and 2 $beta$ -carbomethoxy-3 $beta$ -(4-fluorophenyl)tropane ([ $beta$ -¹¹C]CFT) in the conscious monkey brain. Scopolamine, a muscariniccholinergic antagonist, was used as a modulator of the dopaminergicneuronal system instead of benztropine, which has a slight dopaminetransporter (DAT) inhibitory effect in addition to its muscariniccholinergic receptor inhibitory action (Coyle and Snyder, 1969).In vivo Scatchard plot analysis was applied to evaluate the effectsof scopolamine on binding parameters of [¹¹C]raclopride to dopamine D₂ receptors. Microdialysis studies wereconducted to assess the effects of scopolamine on dopamine concentrationsin the striatal extracellular fluid(ECF).

  MATERIALS AND METHODS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Animals and drugs. Young-adult male rhesus monkeys (Macaca mulatta; n = 4) weighing from 5.5 to 6.5 kg were used for the PETmeasurements. Monkeys were maintained and handled in accordancewith recommendations of the United States National Institutesof Health and also the guidelines of the Central Research Laboratory,Hamamatsu Photonics. They were trained to sit on a chair twicea week over a period of >3 months. Magnetic resonance images (MRI)of all monkeys were obtained with a Toshiba MRT-50A/II (0.5 T)under pentobarbital anesthesia. The stereotactic coordinates ofPET and MRI were adjusted based on the orbitomeatal (OM) linewith a specially designed head holder (Takechi et al., 1994).At least 1 month before the PET study, an acrylic plate, withwhich monkey was fixed to a monkey chair, was attached to thehead under pentobarbital anesthesia as described previously (Onoeet al., 1994).

Scopolamine hydrobromide was obtained from Kyorin Pharmaceutical Co. Ltd. (Tokyo, Japan). Precursors for labeling of [¹¹C]raclopride and [ $beta$ -¹¹C]CFT were purchased from Research Biochemicals (Natick, MA).The enzymes for L[ $beta$ -¹¹C]DOPA synthesis, alanine racemase (EC 5.1.1.1.), D-amino acidoxidase (EC 1.4.3.3.), and $beta$ -tyrosinase (EC 4.1.99.2), werepurchased from Ikeda Food Research Co. Ltd. (Hiroshima,Japan).

Synthesis of [¹¹C]-labeled compounds. Carbon-11 (¹¹C) was produced by ¹⁴N(p, $alpha$ )¹¹C nuclear reaction using a cyclotron (HM-18; Sumitomo Heavy Industry,Tokyo, Japan) at Hamamatsu Photonics PET center and obtained as[¹¹C]CO₂. [ $beta$ -¹¹C]CFT was labeled with ¹¹C by N-methylation of its nor-compound with [¹¹C]methyl iodide prepared from [¹¹C]CO₂. [¹¹C]Raclopride was synthesized by O-methylation of its precursorwith [¹¹C]methyl iodide. The radiochemical and chemical purities usedhere were greater than 98 and 99%, respectively, and the specificradioactivity ranged from 107 to 141 GBq/µmol for [ $beta$ -¹¹C]CFT and from 54.2 to 77.8 GBq/µmol for [¹¹C]raclopride,respectively.

L-[ $beta$ -¹¹C]DOPA was synthesized using a combination of organic synthesis and multi-enzymatic procedures (Bjurling et al., 1990)using an automated synthesizer (Harada et al., 2000). The radiochemicaland chemical purities of L-[ $beta$ -¹¹C]DOPA were better than 98 and 99%,respectively.

After analysis for identification, the solution was passed through a 0.22 µm pore size filter before intravenous administrationto themonkey.

PET scan. Data were collected on a high-resolution PET scanner (SHR-7700; Hamamatsu Photonics, Hamamatsu, Japan) with a transaxialresolution of 2.6 mm full-width at half-maximum and a center-to-centerdistance of 3.6 mm (Watanabe et al., 1997). The PET camera allowed31 slices for imaging to be recordedsimultaneously.

After an overnight fast, animals were fixed to the monkey chair with stereotactic coordinates aligned parallel to the OM line.A cannula was implanted into the posterior tibial vein of themonkey for administration of [¹¹C]-labeled ligands, and another cannula was put into the femoralartery of the other leg to obtain arterial blood samples for scanswith [¹¹C]raclopride and [ $beta$ -¹¹C]CFT.

During PET scans, heart rate, respiration rate, blood pressure, and body temperature were continuously monitored using a lifemonitoring system (Nihon Kohden, Tokyo, Japan). The levels ofcarbon dioxide (PaCO₂), blood oxygen (PaO₂), and pH of arterialblood were measured with a Stat Profile blood gas analyzer (NovaBiochemical, Waltham,MA).

All four monkeys were subjected to PET scans with L-[ $beta$ -¹¹C]DOPA, [¹¹C]raclopride, and [ $beta$ -¹¹C]CFT. Three PET scans with either [¹¹C]-labeled compound were serially performed in the same animalin 1 d. At 30 min after administration of saline, a [¹¹C]-labeled compound was injected through the posterior tibialvein cannula. For second and third scans, at 30 min after administrationof scopolamine (10 or 100 µg/kg), the same [¹¹C]-labeled compound was injected every 3 hr. Because of the veryshort half-life of ¹¹C (20.4 min), the radioisotope used in these studies, a time lagof at least 3 hr between scans provided sufficient time for decayof the radioactivity in the monkeys (~ ofinjected dose), so that the level of radioactivity associatedwith the previous injection of [¹¹C]-labeled compound would not interfere with the nextscan.

PET scans with [¹¹C]raclopride and L-[ $beta$ -¹¹C]DOPA were performed for 64 min with six time frames at 10 sec intervals, six timeframes at 30 sec, 12 time frames at 1 min, followed by 16 timeframes at 3 min. For [ $beta$ -¹¹C]CFT study, PET scans were performed with an additional ninetime frames at 3min.

Kinetic analysis of in vivo binding. Regions of interest (ROI), i.e., the striatum and cerebellum, were identified accordingto MR images of each monkey brain, and the time-activity curvesof L-[ $beta$ -¹¹C]DOPA, [¹¹C]raclopride, and [ $beta$ -¹¹C]CFT in ROIs were obtained as described previously (Tsukada etal., 1999a,b, 2000a,b).

To measure the input function of [¹¹C]raclopride and [ $beta$ -¹¹C]CFT to the brain, arterial blood samples were obtained every 8 secfrom 10 to 66 sec, followed by 96, 156, 246, and 336 sec, andthen 20, 30, 45, and 60 min after tracer injection. For [ $beta$ -¹¹C]CFT, additional samples were taken at 75 and 90 min. Blood sampleswere centrifuged to separate plasma and weighed, and their radioactivitywas measured. For metabolite analysis, methanol was added to someplasma samples (sample/methanol, 1:1) obtained at 42 and 66 secand 5.6, 10, 30, 45, 60, 75, and 90 min after tracer injection,followed by centrifugation. The obtained supernatants were developedwith thin-layer chromatography (TLC) plates (AL SIL G/UV; Whatman,Kent, UK) with a mobile phase of ethylene dichloride/diethyl ether/ethanol/triethylamine,20:20:1:1. The ratio of unmetabolized fraction was determinedusing a phosphoimaging plate (BAS-1500 MAC; Fuji Film Co. Ltd.,Tokyo, Japan). The r_f values of [¹¹C]raclopride and [ $beta$ -¹¹C]CFT were 0.41 and 0.52, respectively. The input functions ofunmetabolized [¹¹C]raclopride and [ $beta$ -¹¹C]CFT were calculated using the data obtained by correction ofthe ratio of the unmetabolized fraction to totalradioactivity.

For quantification of in vivo binding of [¹¹C]raclopride and [ $beta$ -¹¹C]CFT, a kinetic three-compartment analysis method was appliedas described previously (Huang et al., 1986). The time-activitycurves of plasma and of each region were fitted to a three-compartmentmodel with the least-square fitting method using the constrainedK₁/k₂ ratio to the distribution volume in the cerebellum. Thevalues of binding potential (BP) of [¹¹C]raclopride and [ $beta$ -¹¹C]CFT were calculated by determining the ratio of the estimatedk₃ value (association rate) to the estimated k₄ value (dissociationrate) (Tsukada et al., 1999a,b, 2000a,b).

For quantification of L-[ $beta$ -¹¹C]DOPA utilization rate constant in the striatum of the monkey brain, a graphical analysis methodwas applied to calculate dopamine synthesis rate (k₃) as describedpreviously (Tedroff et al., 1991; Tsukada et al., 1996b, 2000a,b).

Scatchard plot analysis. Saturation experiments were performed to examine the effects of scopolamine on in vivo binding parameters(B_max and K_d) of [¹¹C]raclopride (Farde et al., 1989; Tsukada et al., 1996a). Thirtyminutes after administration of scopolamine (10 and 100 µg/kg),[¹¹C]raclopride was injected into monkeys under carrier-free conditionsor together with various amounts (from 3 to 300 µg/kg) of carrierraclopride. The total radioligand concentration of [¹¹C]raclopride in the cerebellum was used as an estimate of thefree radioligand concentration (F) in the striatum. Specific binding(B) was defined as radioactivity in the striatum reduced by F.In the case of [¹¹C]raclopride, the curve for B was fitted to a set of three exponentialfunctions to determine the time point at which B reached a peak(Farde et al., 1989). The values for B and F at these time pointswere used in Scatchard analysis in which the ratio of B/F wasplotted against B (Scatchard, 1949). The apparent in vivo B_maxand K_d values were analyzed using LIGAND software (Munson andRodbard, 1980).

Microdialysis analysis. Microdialysis was performed in the conscious state in the same monkeys used for PET studies as describedpreviously (Tsukada et al., 1999a,b, 2000a,b). A guide cannulawas implanted (anterior, 21 mm; lateral, 3.0 mm) according tothe individual MR images with reference to the stereotactic brainatlas of Snider and Lee (1961), during the procedure for attachmentof the acrylic plate. A microdialysis probe with a membrane region250 µm in diameter and 3 mm in length (Eicom A-I-25-03; Eicom,Tokyo, Japan) was inserted into the striatal region (17.0 mm belowthe dura matter) of the monkey brain via the guide cannula. Theprobe was initially perfused with Krebs'-Henseleit solution (inmM: 118.5 NaCl, 4.7 KCl, 1.2 KH₂PO₄, 1.2 MgSO₄, 1.25 CaCl₂, 25.0NaHCO₃, and 5.6 glucose, pH 7.4) at a rate of 10 µl/min to removedopamine overflow from the damaged tissue. The perfusion ratewas decreased to 5 µl/min 2 hr after insertion of the probe, 75µl samples were collected every 15 min, and the content of dopaminewas measured by HPLC with electrochemical detection. To verifythe exact positioning of the probe, 5 µl of China ink was injectedvia the guide cannula at the end of the experiments. Animals wereanesthetized with sodium pentobarbital and decapitated. The brainswere quickly removed, coronal sections were cut on a cryostat,and the location of the probe implantation site was determinedvisually.

The averaged data obtained from 0 to 120 min before administration of saline or scopolamine were used as " baseline" data.Saline or scopolamine (10 and 100 µg/kg) was administered 120min after the start of sampling. GBR12909 at a dose of 0.5 mg/kgwas administered 30 min after saline or scopolamine (10 and 100µg/kg). The striatal ECF dopamine level was expressed as percentageofbaseline.

Statistical analysis. Results are expressed as means ± SD. Comparison between conditions was performed using the paired, two-tailedStudent's t test, and a probability level of p < 0.05 was consideredstatisticallysignificant.

  RESULTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Under the control conditions with saline administration, the summated PET images from 37 to 64 min after injection and thetime-activity curves indicated high uptake of L-[ $beta$ -¹¹C]DOPA (Fig. 1A), [¹¹C]raclopride (Fig. 2A), and [ $beta$ -¹¹C]CFT (Fig. 3A) in the striatum, and low uptake in the cerebellumof the conscious monkey brain. The striatal radioactivity associatedwith L-[ $beta$ -¹¹C]DOPA reached a peak 5 min after injection and remained at thiselevated level to the end of the scan (Fig. 1A). The maximum accumulationof radioactivity in the striatum occurred ~10 min after injectionof [¹¹C]raclopride and decreased gradually thereafter (Fig. 2A). Thetime-activity curve of [ $beta$ -¹¹C]CFT in the striatum increased with time during the experimentalperiod (Fig. 3A). In the cerebellum, the time-activity curvesof these labeled compounds showed peak values within 5 min afterinjection, followed by gradual decreases with time (Figs. 1A,2A, 3A).

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Figure 1. Effects of scopolamine on the time-activity curves of L-[ $beta$ -¹¹C]DOPA in the brain (A) and the k₃ value (B). Saline or scopolamine (10 or 100 µg/kg) was administered 30 min before L-[ $beta$ -¹¹C]DOPA injection. PET scan was started immediately after tracer injection, and image data were collected for 64 min. A, ROIs were identified according to MRI of the same animal. The radioactivity in each striatum (St) and cerebellum (Ce) were plotted against time after tracer injection. B, The time course of changes in radioactivity in the striatum as a ratio to that in the cerebellum was expressed as a function of the normalized integral of each cerebellar radioactivity. The slope of the calculated regression line represents k₃ value.

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Figure 2. Effects of scopolamine on the time-activity curves of [¹¹C]raclopride in the brain (A) and in the arterial plasma (B). Saline or scopolamine (10 or 100 µg/kg) was administered 30 min before [¹¹C]raclopride injection. PET scan was started immediately after tracer injection, and image data were collected for 64 min. A, ROIs were identified according to MRI of the same animal. The radioactivity in each striatum (St) and cerebellum (Ce) were plotted against time after tracer injection. B, Time-activity curve of unmetabolized [¹¹C]raclopride. Unmetabolized [¹¹C]raclopride was calculated by correction of relative to total radioactivity with the ratio of the unmetabolized fraction at each time point.

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Figure 3. Effects of scopolamine on the time-activity curves of [ $beta$ -¹¹C]CFT in the brain (A) and in the arterial plasma (B). Saline or scopolamine (10 or 100 µg/kg) was administered 30 min before [ $beta$ -¹¹C]CFT injection. PET scan was started immediately after tracer injection, and image data were collected for 91 min. A, ROIs were identified according to MRI of the same animal. The radioactivity in each striatum (St) and cerebellum (Ce) were plotted against time after tracer injection. B, Time-activity curve of unmetabolized [ $beta$ -¹¹C]CFT. Unmetabolized [ $beta$ -¹¹C]CFT was calculated by correction of relative to total radioactivity with the ratio of the unmetabolized fraction at each time point.

In plasma, the curves of total radioactivity associated with [¹¹C]raclopride (Fig. 2B) and [ $beta$ -¹¹C]CFT (Fig. 3B) showed peaks ~30 sec after slow bolus intravenousinjection and declined rapidly thereafter. Metabolite analysisby TLC and a phosphoimaging system indicated that [¹¹C]raclopride and [ $beta$ -¹¹C]CFT were gradually metabolized to very polar metabolites, whichremained at the origin, and the ratios of radioactivity in unmetabolizedlabeled compounds to the in total (unmetabolized plus metabolized)were 0.72 and 0.22 at 60 min after injection, respectively (datanot shown). The input functions of unmetabolized [¹¹C]-labeled compounds were calculated using the data obtained bycorrection of total radioactivity relative to the metabolic ratio(data not shown). In general, the input functions of [¹¹C]raclopride and [ $beta$ -¹¹C]CFT into the brain were not significantly affected by administrationof scopolamine (Figs. 2B, 3B).

Systemic intravenous administration of scopolamine at doses of 10 and 100 µg/kg caused dose-dependent increases in the uptakeof L-[ $beta$ -¹¹C]DOPA in the striatum with no significant changes in the radioactivitycurves in the cerebellum (Fig. 1A). These alterations in the striatalkinetics of L-[ $beta$ -¹¹C]DOPA caused dose-dependent enhancement of the kinetic valuesof dopamine synthesis rate (k₃), as calculated using the time-activitycurve of the cerebellum as the input function (Figs. 1B, 4A).

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Figure 4. Effects of scopolamine on dopamine synthesis rate, D₂ receptor binding, and transporter availability, as measured with L-[ $beta$ -¹¹C]DOPA (A), [¹¹C]raclopride (B), and [ $beta$ -¹¹C]CFT (C), respectively. A, The time course of changes in radioactivity in the striatum (St) as a ratio of that in the cerebellum (Ce) was expressed as a function of the normalized integral of each cerebellar radioactivity. The values of k₃ are represented by the slope of the calculated regression line shown in Figure 1B. B, C, The time-activity curves of unmetabolized [¹¹C]raclopride and [ $beta$ -¹¹C]CFT in arterial plasma, shown in Figures 2B and 3B, were used as input functions into the brain, and the three-compartment model was fitted to the time-activity curve of specific binding in the striatum. The binding potential was calculated as the ratio of the association rate (k₃) to the dissociation rate (k₄). Data are expressed as means ± SD for four animals per treatment condition. *p < 0.05 versus respective saline control (dose of 0). **p < 0.05 versus respective scopolamine at a dose of 10 µg/kg.

The administration of scopolamine (10 and 100 µg/kg) resulted in a dose-dependent reduction of [¹¹C]raclopride uptake in the striatum, with no significant changesin those in the cerebellum or arterial plasma (Fig. 2A,B). Thesealterations in the striatal kinetics of [¹¹C]raclopride caused a dose-dependent decrease in the binding potential(BP = k₃/k₄) as calculated using each plasma time-activity curveas an input function (Fig. 4B).

The administration of scopolamine (10 and 100 µg/kg) caused a dose-dependent increase in the uptake of [ $beta$ -¹¹C]CFT in the striatum with no significant changes in the radioactivitycurves of arterial plasma (Fig. 3A,B), indicating the dose-dependentincrease in the BP of [ $beta$ -¹¹C]CFT as shown in Figure 4C.

As shown in Figure 5, the effects of scopolamine (10 and 100 µg/kg) on dopamine level in the striatal ECF were evaluated bymicrodialysis in the monkey brain. Microdialysis was performedsimultaneously with PET scans of [¹¹C]raclopride. The baseline level of dopamine was 6.5 ± 1.9 fmol/µl(n = 4) in the striatum of conscious monkeys. Administration ofscopolamine at any dose used here resulted in no significant changesin the striatal ECF dopamine level (Fig. 5A). When GBR12909, aspecific DAT inhibitor, was administered at a dose of 0.5 mg/kgin saline-treated animals, it significantly increased dopaminelevel in the striatal ECF of the monkey brain (Fig. 5B). Interestingly,scopolamine preadministered 30 min before the administration ofGBR12909 at the same dose as used in the saline condition furtherfacilitated the GBR12909-induced striatal ECF dopamine enhancementin a dose-dependent manner (Fig. 5B).

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Figure 5. Effects of scopolamine (A) and/or GBR12909 (B) on dopamine concentration in the striatal ECF of the monkey brain. A microdialysis probe was inserted into the striatal region via the guide cannula. The probe was perfused with Krebs'-Henseleit solution (pH 7.4) at a rate of 5 µl/min. Samples were collected every 15 min, and the content of dopamine was measured by HPLC with electrochemical detection. The averaged data obtained from 0 to 120 min without any infusion were used as baseline data. Saline or scopolamine at doses of 10 or 100 µg/kg was administered 120 min after the start of sampling (arrow with S). GBR12909 at a dose of 0.5 mg/kg was administered 30 min after saline or scopolamine administration (arrow with G). The striatal ECF dopamine level was expressed as percentage of baseline.

To clarify the mechanism(s) by which scopolamine modulates dopamine D₂ availability in vivo, [¹¹C]raclopride was injected into monkeys together with various amounts(from 3 to 300 µg/kg) of unlabeled carrier ligand raclopride.[¹¹C]Raclopride with carrier ligand was injected 30 min after theadministration of scopolamine (10 and 100 µg/kg). The additionof increasing amounts of unlabeled carrier ligand dose-dependentlyreduced the amounts of bound radiolabeled ligand (Fig. 6A). Inthese studies, a significant decrease in radioactivity of bound[¹¹C]raclopride in the striatum over the time span of the PET studywas found, and the results were similar in both saline- and scopolamine-treatedgroups. In contrast, in the cerebellum, no changes were observedin the amount of radioactivity of [¹¹C]raclopride over the range of amount of unlabeled carrier addedin both cases (Fig. 6A). The free radioligand concentration (F)in the striatum was assumed to be comparable with the radioligandconcentration in the cerebellum. The specific binding (B) in thestriatum was calculated by subtracting the radioligand concentrationmeasured in the cerebellum from total binding in the striatum.For Scatchard analysis of the binding of [¹¹C]raclopride in vivo, equilibrium values for B and F were obtainedwhen the B value was maximum. The maximum accumulation occurredbetween 12 and 15 min after injection of [¹¹C]raclopride. The Scatchard plot revealed a linear curve for [¹¹C]raclopride in saline-treated, as well as scopolamine-treated,monkeys (Fig. 6B). The administration of scopolamine resultedin dose-dependent reduction of the slopes of the curves determinedwith [¹¹C]raclopride, suggesting the alteration of the affinity (1/K_d)of D₂ receptors (Fig. 6B). In contrast, scopolamine did not affectthe intercept with the x-axis in [¹¹C]raclopride, which provided the maximum number of binding sites(B_max) of D₂ receptors (Fig. 6B).

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Figure 6. Saturation studies (A) and Scatchard plot analysis (B) of in vivo binding of [¹¹C]raclopride in the monkey brain. Monkeys were administered saline or scopolamine (10 or 100 µg/kg, i.v.) 30 min before injection of [¹¹C]raclopride under carrier-free conditions or with various doses of carrier ligand ranging from 3 to 300 µg/kg. A, The radioactivities in striatum and cerebellum at 12-15 min after tracer injection were expressed as percentage of dose per milliliter. Data are expressed as means ± SD for four animals per treatment group. Radioactivity in the striatum (open symbols) or cerebellum (filled symbols). B, The total radioligand concentration in the cerebellum was used as the free radioligand concentration (Free) in the striatum. Specific binding (Bound) was defined as radioactivity in the striatum reduced with Free. The average values (n = 4 for each points) for Bound and Free were used in a Scatchard analysis in which the ratios Bound/Free were plotted against Bound.

  DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

This is the first study to demonstrate the effects of muscarinic cholinergic modulation on the striatal dopamine neuronalactivity by simultaneous multi-parametric assessment of dopaminesynthesis, D₂ receptor binding and DAT availability as measuredby PET in the same nonhuman primates in the consciousstate.

We reported previously that benztropine, a muscarinic cholinergic antagonist with slight DAT inhibitory activity, inducedthe reduction of [¹¹C]raclopride binding in the conscious monkey brain as measuredby PET (Tsukada et al., 1999a). These observations were consistentwith the previous report of inhibition of [¹¹C]raclopride binding by cholinergic blockade induced by scopolaminein anesthetized baboons (Dewey et al., 1993b). Although theseauthors speculated that the reduced [¹¹C]raclopride binding was attributable to the increase in synapticdopamine level via neuronal interactions, it did not demonstratea clear relationship between the doses administered and the reductionin magnitude of [¹¹C]raclopride binding (Dewey et al., 1993b). The lack of microdialysisdata as measured in the same animals used in the PET study impairedinterpretation of the previous data. The change in synaptic dopaminelevel does not always represent a reasonable explanation for thealterations of dopamine D₂ receptor availability in vivo as measuredby PET with [¹¹C]raclopride. As we have demonstrated previously, although administrationof benztropine-induced elevation of dopamine concentration inthe striatal ECF as measured by microdialysis, the magnitude ofthe elevation of dopamine level by benztropine was much lowerand of shorter duration than those evoked by direct dopamine enhancers,such as GBR12909 and methamphetamine (Tsukada et al., 1999a).However, benztropine induced significant reduction of [¹¹C]raclopride in the striatum of conscious monkeys to a similarextent as that induced by the direct dopamine enhances (Tsukadaet al., 1999a). Furthermore, benztropine also decreased [¹⁸F]NMSP (Dewey et al., 1990), which was expected to be more stableagainst alterations of dopamine concentration than [¹¹C]raclopride because of its 10 times higher affinity to dopamineD₂ receptors. As shown in the present study, scopolamine did notalter the apparent static dopamine concentration in the striatalECF; however, scopolamine reduced the in vivo binding of [¹¹C]raclopride. Amphetamine reduced the in vivo binding of both[³H]/[¹¹C]raclopride (Dewey et al., 1991, 1993a; Young et al., 1991) and[³H]/[¹⁸F]NMSP (Dewey et al., 1991; Logan et al., 1991; Young et al.,1991). Isoflurane has been reported to increase synaptic dopaminelevels (Opacka-Juffry et al., 1991); however, it decreased thein vivo binding of [¹¹C]raclopride to a much lesser extent than that of [¹¹C]NMSP (Kobayashi et al., 1995). Subanesthetic doses of ketamine,a noncompetitive antagonist of NMDA receptors, decreased the striatalbinding of [¹¹C]raclopride in human subjects, suggesting that ketamine increasedthe striatal dopamine concentration by ketamine (Smith et al.,1997). However, the results of previous microdialysis studiesdemonstrated that NMDA antagonists [ketamine and (+)-5-methyl-10,11-dihydro-5H-dibenzo(a,d)cyclohepten-5,10-iminehydrogen maleate (MK-801)] increased (Moghaddam et al., 1990;French 1994; Verma and Moghaddam, 1996), decreased (Kashiharaet al., 1990), or did not change (Bacopoulos et al., 1979; Koshikawaet al., 1988; Onoe et al., 1994; Tsukada et al., 2000a) dopamineconcentration in the striatum. It is of interest that MK-801 significantlyincreased stereotypic behavior but did not affect the striataldopamine concentration (Weihmuller et al., 1991). Our previousstudies indicated that ketamine paradoxically altered dopamineD₂ receptor availability as measured by [¹¹C]raclopride (increased binding) and [¹¹C]NMSP (decreased binding) without any apparent change in dopamineconcentration in the striatal ECF (Onoe et al., 1994; Tsukadaet al., 2000a). Modulation using reserpine, which depletes endogenousdopamine, induced the increased binding of [³H]/[¹¹C]raclopride (Inoue et al., 1991; Ginovart et al., 1997) but thedecreased binding of [³H]NMSP (Inoue et al., 1991) (for review, see Laruelle, 2000).Interestingly, [¹¹C]raclopride binding in vivo was also markedly reduced in thehuman striatum during video game playing with hand movement, andthe degree of reduction showed a reverse correlation with theperformance of the game, showing at most 50% reduction of binding(Koepp et al., 1998). In this study, the reduction of [¹¹C]raclopride was simply attributed to the increased dopamine inthe striatal synaptic cleft. However, in the animal experimentwith conscious monkeys, 50% reduction of [¹¹C]raclopride required the administration of methamphetamine at1 mg/kg or more, which corresponds to an almost 100-fold higherdose than that used by drug abusers daily (Tsukada et al., 1999a).Together, the alteration of affinity or availability change ofreceptor sites induced by the neuronal interactions should alsobe taken into account for the alteration of dopamine D₂ receptoravailability in vivo as measured by PET with [¹¹C]raclopride, as well as [¹¹C]NMSP. In fact, the present results obtained by Scatchard plotanalysis in vivo demonstrated that cholinergic modulation elicitedalteration of the apparent affinity (1/K_d) of dopamine D₂ receptors,without any alteration of the apparent maximum numbers of bindingsites (B_max) of dopamine D₂ receptors, resulting in the reducedbinding potential BP = k₃/k₄ = B_max/K_d of [¹¹C]raclopride in vivo in the monkey brain as measured byPET.

It was hypothesized previously that the altered affinity of dopamine D₂ receptors measured by [¹¹C]raclopride accounted for the apparent static concentration ofendogenous dopamine in the synaptic cleft (Farde et al., 1995).Although a reduction in affinity of [¹¹C]raclopride was consistent with a competitive model between endogenousdopamine and [¹¹C]raclopride binding to receptors, the present results did notsupport the previous hypothesis, because similar analytical proceduresrevealed that scopolamine administration resulted in decreasedaffinity of dopamine D₂ receptors as measured by [¹¹C]raclopride without any changes in apparent static dopamine concentrationin the striatal ECF as measured by microdialysis. The presentresults obtained from the assessments of dopamine synthesis andDAT availability provide the important insight into these mechanisms.Systemic administration of scopolamine produced the simultaneousand dose-dependent enhancement of dopamine synthesis and DAT availabilityas measured by L-[ $beta$ -¹¹C]DOPA and [ $beta$ -¹¹C]CFT, respectively. Previous studies demonstrated that the utilizationrate constant (k₃) of L-[ $beta$ -¹¹C]DOPA was increased by enhancement of the activity of tyrosinehydroxylase (EC 1.14.16.2) (Tsukada et al., 1996b), which isthe rate-limiting enzyme in the synthesis of catecholamines (Nagatsuet al., 1964), accompanied with increased dopamine release intothe synaptic cleft (Tsukada et al., 1994b). As observed in thepresent study, administration of scopolamine increased the utilizationrate constant (k₃) of L-[ $beta$ -¹¹C]DOPA in a dose-dependent manner, suggesting that dopamine synthesiswas enhanced in addition to dopamine release into the synapticcleft of the striatum. However, microdialysis assay indicatedno significant increase in dopamine concentration in the striatalECF in the present study. One possible explanation for this discrepancyis that the change in dopamine concentration in ECF measured bymicrodialysis does not reflect the "true" dopamine release intothe synaptic cleft as suggested previously using voltammetry (Kuhret al., 1984; Kuhr and Wightman, 1986; May, 1988; Grace, 1993).This is unlikely however, because our previous study demonstratedthat the same microdialysis assay could detect the enhancementof dopamine synthesis in the neurons (Tsukada et al., 1994a,b),the facilitation of dopamine release by methamphetamine (Tsukadaet al., 1999a), and also the increase in the synaptic dopaminelevel induced by the inhibition of DAT by cocaine and GBR12909(Tsukada et al., 1999a,b). Then the resulting increase in dopamineconcentration in the striatal ECF was confirmed by measurementsof "cold" endogenous dopamine (Tsukada et al., 1994a, 1999a,b)and [¹¹C]-labeled "hot" dopamine converted from L-[ $beta$ -¹¹C]DOPA (Tsukada et al., 1994b). The precise mechanisms of enhancedDAT availability by scopolamine remain unclear yet. Because ofthe slow kinetics of [ $beta$ -¹¹C]CFT in the brain, its delivery is often affected by the changein regional cerebral blood flow (rCBF); that is, the increasedrCBF might result in the enhanced uptake of [ $beta$ -¹¹C]CFT as observed in the present study. However, changes in rCBFmight not account for the enhanced DAT availability by scopolamine,because our previous result demonstrated that the administrationof scopolamine at the doses of 10 and 100 µg/kg decreased, notincreased, rCBF in the conscious monkey brain (Tsukada et al.,1997). Some compensatory mechanisms with negative feedback systemmight be involved in this enhanced DAT availability for the regulationof increased dopamine release. Our recent results also revealedthat ketamine infusion dose-dependently decreased [¹¹C]raclopride binding with no significant changes in dopamine concentrationin the striatal ECF as observed in the case of scopolamine, andalso that ketamine increased both dopamine synthesis and DAT availabilityas measured by L-[ $beta$ -¹¹C]DOPA and [ $beta$ -¹¹C]CFT, respectively (Tsukada et al., 2000a). Microdialysis usingthe DAT inhibitor GBR12909 demonstrated that preadministrationof scopolamine further facilitated the increase in striatal ECFdopamine level induced by DAT inhibition. The present resultsfurther indicated the facilitation of dopamine turnover by scopolamineand also strongly supported the usefulness of the combined useof L-[ $beta$ -¹¹C]DOPA and [ $beta$ -¹¹C]CFT for the assessment of dopamine turnover. Together, theseresults suggested that the modulation of muscarinic cholinergic,as well as glutamatergic, neuronal activities altered dopamineturnover in the striatum by simultaneous enhancement of the dynamicsof dopamine synthesis and DAT availability to the same extent,resulting in no apparent marked changes in ECF dopamine concentrationas measured bymicrodialysis.

In conclusion, the present results revealed that scopolamine reduced dopamine D₂ receptor binding in vivo by increasing dopamineturnover rate, not by elevating apparent static dopamine concentrationin the synaptic cleft, resulting in the altered receptor affinityor availability. That is, the regulatory mechanism of dopamineneuronal transmission might be explained by the "rate" theorydefined as the dynamics of dopamine binding to receptors and synapticturnover of dopamine, not by the conventional "occupancy" theory.These results further support our hypothesis that alteration ofthe binding of radiolabeled ligands in vivo as measured by PETmight not simply be modulated by the apparent static synapticconcentration of dopamine (Tsukada et al., 1999a, 2000a). Theseobservations will be important for research and diagnosis of neuropsychiatricand neurodegenerative diseases using the functional imaging modalitiesof PET and single photon emission tomography with labeledcompounds.

  FOOTNOTES

Received May 1, 2000; revised June 28, 2000; accepted June 30, 2000.

This work was supported in part by Special Coordination Funds for Promoting Science and Technology of the Science and TechnologyAgency of the Japanese Government. We are grateful Kengo Satoand Dai Fukumoto for their excellent technicalassistance.
Correspondence should be addressed to Dr. Hideo Tsukada, Central Research Laboratory, Hamamatsu Photonics K.K., 5000 Hirakuchi,Hamakita, Shizuoka 434-8601, Japan. E-mail: tsukada{at}crl.hpk.co.jp.

  REFERENCES

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

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