Enhanced Amphetamine- and K+-Mediated Dopamine Release in Rat Striatum after Repeated Amphetamine: Differential Requirements for Ca2+- and Calmodulin-Dependent Phosphorylation and Synaptic Vesicles

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The Journal of Neuroscience, May 15, 1999, 19(10):3801-3808

Enhanced Amphetamine- and K⁺-Mediated Dopamine Release in Rat Striatum after Repeated Amphetamine: Differential Requirements for Ca²⁺- and Calmodulin-Dependent Phosphorylation and Synaptic Vesicles
Lana Kantor, G. H. Keikilani Hewlett, and Margaret E. Gnegy
Department of Pharmacology, University of Michigan Medical School, Ann Arbor, Michigan 48109-0634

  ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

After cessation of repeated, intermittent amphetamine, we detected an emergent Ca²⁺-dependent component of amphetamine-induced dopamine release andan increase in calmodulin and Ca²⁺- and calmodulin-dependent protein kinase activity in rat striatum.This study examined the involvement of calmodulin-dependent proteinkinase II (CaM kinase II) and synaptic vesicles in the enhancedCa²⁺-dependent dopamine release in response to amphetamine or K⁺ in rat striatum. Rats were pretreated for 5 d with 2.5 mg/kgamphetamine or saline and withdrawn from drug for 10 d. The selectiveCaM kinase II inhibitor KN-93 (1 µM), but not the inactive analogKN-92, attenuated the Ca²⁺-dependent amphetamine-mediated dopamine release from amphetamine-pretreatedrats but had no effect in saline-pretreated controls. [³H]Dopamine uptake was unaltered by repeated amphetamine or KN-93and was Ca²⁺ independent. Striatal dopamine release stimulated by 50 mM KClwas enhanced twofold after repeated amphetamine compared withthat in saline controls but was unaffected by KN-93. To examinethe requirement for dopaminergic vesicles in the Ca²⁺-dependent dopamine release, we administered reserpine to saline-and amphetamine-pretreated rats 1 d before killing. Reserpinepretreatment did not affect amphetamine-mediated dopamine releasefrom either pretreatment group but completely ablated K⁺-mediated dopamine release. Reserpine did not disrupt the abilityof 1 µM KN-93 to block the Ca²⁺-dependent amphetamine-mediated dopamine release from amphetamine-pretreatedrats. The results indicate that the enhanced dopamine releaseelicited by amphetamine from chronically treated rats is dependenton Ca²⁺- and calmodulin-dependent phosphorylation and is independentof vesicular dopamine storage. On the contrary, the enhanced depolarization-mediatedvesicular dopamine release is independent of Ca²⁺- and calmodulin-dependentphosphorylation.

Key words: repeated amphetamine; dopamine transport; reserpine; CaM kinase II; depolarization; phosphorylation

  INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The catecholamine dopamine (DA) can be released from terminals and dendrites by exocytosis, a Ca²⁺- and synaptic vesicle-dependent process, or by a Ca²⁺-independent, plasmalemma transporter-mediated mechanism thatis used by the psychostimulant amphetamines (AMPHs) (Raiteri etal., 1979). Many behavioral effects elicited by AMPH are attributedto its ability to release DA from presynaptic nerve terminalsand to inhibit the reuptake of DA from the synapse (Seiden etal., 1993). DA release after acute administration of AMPH is Ca²⁺ independent; it relies on cytosolic DA and vesicular DA thatpermeates into the neuronal cytoplasm from synaptic vesicles (Chiuehand Moore, 1975; Raiteri et al., 1979; Jones et al., 1998). Repeated,intermittent treatment of rats with AMPH or cocaine leads to anenhanced release of DA from areas such as the striatum and nucleusaccumbens in response to stimuli such as AMPH or depolarization(Robinson and Becker, 1982; Robinson et al., 1985; Castañedaet al., 1988; Kolta et al., 1989; Wolf et al., 1993; Pierce andKalivas, 1997a). The enhanced component of the AMPH-induced DArelease after repeated AMPH or cocaine is distinguished from thatreleased in nontreated rats by its Ca²⁺ dependency (Warburton et al., 1996; Iwata et al., 1997; Pierceand Kalivas, 1997a). We have identified additional Ca²⁺-related activities in rat striatum that develop after repeated,intermittent AMPH. After cessation of repeated AMPH, we foundan increase in the Ca²⁺-binding protein calmodulin (CaM) and in the activity of Ca²⁺- and CaM-dependent protein kinase II (CaM kinase II) in striatalsynaptosomes as well as an increase in the phosphorylated stateof the vesicular protein synapsin I at the CaM kinase II substratesite (Iwata et al., 1996, 1997). Both CaM kinase II and synapsinI are involved in neurotransmitter release; CaM kinase II enhancedCa²⁺-dependent glutamate release from nerve endings purportedly viaan enhanced phosphorylation of synapsin I (Llinas et al., 1991;Nichols et al., 1992). Inhibitors of CaM kinase II blocked a Ca²⁺-dependent component of amphetamine-mediated DA release in thenucleus accumbens of rats treated with repeated cocaine (Pierceand Kalivas, 1997a) and the sensitized locomotor behavior (Pierceet al., 1998).

The goal of the present study was to examine the role of CaM kinase II in the Ca²⁺-dependent component of DA release in rat striatum after repeatedAMPH in response to a challenge with AMPH. We also investigatedwhether the enhanced depolarization-mediated DA release afterrepeated, intermittent AMPH was dependent on CaM kinase II. Thesource of the releasable pool of DA affected by an AMPH challengeafter a repeated AMPH treatment is unknown. Synaptic vesiclescould be integral to DA release by both stimuli because DA releasein response to both depolarization and AMPH is enhanced afterrepeated AMPH. To determine whether synaptic vesicles were a sourceof DA for the enhanced DA release after repeated AMPH, we examinedwhether reserpine treatment, which depletes vesicular DA, wouldabolish the amphetamine-mediated Ca²⁺-dependent DA release elicited by the repeatedAMPH.

  MATERIALS AND METHODS

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Repeated AMPH regimen. Female Holtzman rats (179-190 gm; Harlan Sprague Dawley, Indianapolis, IN) were given intraperitonealinjections of AMPH (2.5 mg/kg) or saline once a day for 5 d. Saline-and AMPH-pretreated rats were killed 10 d after the last injection.This treatment was chosen because it produces a behavioral sensitizationin response to a challenge dose of AMPH (Robinson and Becker,1982).

Striatal slice preparation. Rats were killed by decapitation, and the striatum was removed and dissected on ice using a brain-cuttingblock as described (Heffner et al., 1980). The striatal tissueof each rat was divided into 1 mm³ pieces and placed immediately into ice-cold Krebs' Ringer buffer(KRB) containing 125 mM NaCl, 2.7 mM KCl, 1 mM MgCl₂, 1.2 mM CaCl₂,1.2 mM KH₂PO₄, 10 mM glucose, 24.9 mM NaHCO₃, 0.25 mM ascorbicacid, and 10 µM pargyline. The buffer was oxygenated with 95%O₂/5% CO₂ for 1 hr, with pH at 7.4.

DA release assay. Striatal slices were weighed and placed into a designated chamber of a Brandel SF-12 superfusion apparatus(Gaithersburg, MD) onto a Whatman GF/B glass filter (Maidstone,UK). Superfusion chambers were maintained at 37°C, and mediumwas perfused through the chambers at 100 µl/min. Samples werecollected at 5 min intervals. All chambers were perfused withKRB or drug for 30 min, followed by a 2.5 min bolus of the followingdrug combinations: 1 µM AMPH, 1 µM AMPH + 10 µM KN-93, 10 µM KN-93alone, and KRB as control. The bolus of AMPH was given at fraction7. Analysis of the time to travel through the tubing demonstratedthat the bolus would arrive at the tissue at fraction 9. In someexperiments, KN-92 was substituted for KN-93. Experiments measuringdepolarization contained 50 mM KCl or 50 mM KCl + 1 µM KN-93.In these experiments, Na⁺ was commensurately lowered in the KRB to maintain osmolarity.The bolus drug combinations were replaced with fresh KRB or withKN-93 and/or KN-92, and sample collection continued for 40 moreminutes. Samples were collected into vials containing 25 µl ofinternal standard solution [0.05N HClO₄, 4.55 mM dihydroxybenzylamine(DHBA), 1 M metabisulfate, and 0.1 M EDTA]. Samples were storedat $-$ 70°C until analysis. The DA content of the samples was analyzedby HPLC with electrochemical detection using DHBA as an internalstandard (Becker et al., 1984). Statistical significance was determinedusing one-way ANOVA with a post-test Tukey-Kramer multiple comparisonanalysis or by Student's ttest.

Reserpine treatment and total DA measurement. Female Holtzman rats were pretreated with repeated AMPH or saline as discussedabove. On day 9 after the last dose of drug, rats were injectedsubcutaneously with 5 mg/kg reserpine or vehicle (1.5% glacialacetic acid) and killed 18 hr later. DA was measured in each striatumto determine the degree of depletion and was, as we found previously(Kantor and Gnegy, 1998), depleted 95% in both saline- and AMPH-pretreatedrats.

[³H]DA uptake. Striatal slices from AMPH- and saline-pretreated rats were weighed, placed into vials containing KRB with andwithout 1.2 mM CaCl₂ at 37°C for 5 min, and incubated for 20 moreminutes in the presence or absence of 10 µM KN-93, 10 µM nomifensine,or 5 µM GBR-12935. After preincubation, [³H]DA (18.3 Ci/mmol) was added to a concentration of 33 nM, andthe incubation proceeded for an additional 5 min. The reactionwas terminated by the addition of 10 ml of ice-cold saline followedby filtration on GF/C filters (Whatman) and two more saline washes.Filters were counted in ScintiVerse BD in a Beckman LS 5800 scintillationcounter. Data were adjusted for the weight of theslices.

Drugs. AMPH was obtained from the University of Michigan Laboratory of Animal Medicine (Ann Arbor, MI). HPLC-grade chemicalswere purchased from American Bioanalytical (Natick, MA). KN-93,KN-92, KN-62, and GBR-12935 were purchased from Calbiochem (LaJolla, CA), and reserpine was obtained from Research Biochemicals(Natick, MA). Nomifensine was the generous gift of Dr. James Woods(Department of Pharmacology, University of Michigan, Ann Arbor,MI).

  RESULTS

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Effect of AMPH challenge on DA release from pretreated rats

The endogenous DA released in response to 1 µM AMPH was measured in striatal slices 10 d after the last pretreatment doseof saline or AMPH (2.5 mg/kg per day for 5 d). As shown in Figure1, AMPH-mediated DA release from striatal slices was twofold greaterfrom AMPH-pretreated rats than from saline-pretreated rats. Baselinevalues did not differ.

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Figure 1. AMPH-mediated DA release in AMPH- and saline-pretreated rats. Female Holtzman rats were pretreated with saline (triangles) or AMPH (squares) as described in Materials and Methods. DA release from the striatal slices was measured in response to AMPH (closed symbols) or KRB (open symbols) as described in Materials and Methods and reported as picomoles of DA per milligram wet weight (ww) ± SEM. Drugs given as a 2.5 min bolus at fraction 7 will reach the slices at fraction 9 (n = 3). A-A and S-A represent DA release from AMPH (A)- and saline (S)-pretreated rats after perfusion with 1 µM AMPH. A-KRB and S-KRB indicate basal DA levels from striatal slices from A- and S-pretreated rats. By the use of ANOVA to compare values for fraction 10, the peak DA responses differ (p < 0.0001). In post hoc Tukey-Kramer tests, S-KRB and A-KRB differ from S-A at p < 0.05 and A-A at p < 0.001. S-A differs from A-A at p < 0.001.

Effect of KN-93 and KN-92 on AMPH-mediated DA release in pretreated rats

The effect of the selective CaM kinase II inhibitor KN-93 and its inactive analog KN-92 on AMPH-induced DA release in striatalslices from saline- and AMPH-pretreated rats was examined. At10 µM, KN-93 had no effect on either basal DA levels or AMPH-mediatedDA release in saline-pretreated rats (Fig. 2A). KN-93, however,did significantly inhibit AMPH-induced DA release in AMPH-pretreatedrats (Fig. 2B). The degree of inhibition was ~50%; the amountof remaining DA released was equal to the level of AMPH-inducedDA release in slices from saline-pretreated rats. At 10 µM, KN-92,the inactive analog of KN-93, had no effect on basal levels orDA released by 1 µM AMPH in either AMPH- or saline-pretreatedrats (Fig. 2C,D). The same results were seen when striatal tissueswere pretreated with a different inhibitor of CaM kinase II, KN-62.In striatal slices from saline-pretreated rats, values for peakDA released in response to 1 µM AMPH in the absence and presenceof 5 µM KN-62 are 0.34 and 0.30 pmol/mg wet weight, respectively.In AMPH-pretreated rats, values for DA released in response to1 µM AMPH in the absence and presence of 5 µM KN-62 are 0.93 and0.44 pmol/mg wet weight, respectively. Values are the averagefrom two experiments whose values did not differ >10%.

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Figure 2. The effect of KN-93 and KN-92 on AMPH-mediated DA release in AMPH- and saline-pretreated rats. Rats were given repeated saline (A, C) or AMPH (B, D), and striatal slices were analyzed for DA release as described in Materials and Methods. DA release in striatal slices was measured in response to AMPH (closed symbols) or KRB (open symbols) in the absence (squares) or presence (diamonds) of 10 µM KN-93 or 10 µM KN-92. Results are reported as picomoles of DA per milligram wet weight (ww) ± SEM (n = 3). A, C, The effect of KN-93 or KN-92 on basal and AMPH-mediated DA release in saline-pretreated rats. B, D, The effect of KN-93 or KN-92 on AMPH-mediated DA release from AMPH-pretreated rats. Statistical analyses were performed using a one-way ANOVA with Tukey-Kramer post hoc analysis on the peak AMPH response, fraction 10 (n = 3). A, C, ANOVA, p = 0.01; p < 0.05 for AMPH (A) compared with KN-93 (KN93) or KN-92 (KN92) alone and KRB. B, ANOVA, p < 0.0001; p < 0.001 for KRB and KN93 alone compared with A; p < 0.05 for KRB and KN93 alone compared with KN93+A; and p < 0.01 for A compared with KN93+A. D, ANOVA, p < 0.001; p < 0.01 for KRB and KN92 alone compared with A and KN92+A.

Depolarization-mediated DA release and the effect of KN-93 after repeated AMPH

Castañeda et al. (1988) demonstrated that electrical- and depolarization-mediated DA release was enhanced in rats treatedwith a sensitizing regimen of repeated AMPH that differed fromthis regimen. To ensure that there was enhanced depolarization-mediatedDA release in our regimen, we perfused striatal slices from saline-and AMPH-pretreated rats with 50 mM KCl. As shown in Figure 3,depolarization-mediated DA release was increased twofold afterwithdrawal from the repeated AMPH regimen compared with that insaline controls. However, the K⁺-mediated DA release was not altered by KN-93 (Fig. 4A,B) or KN-92(data not shown) alone in striatal slices from either saline-or AMPH-pretreated rats.

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Figure 3. K⁺-mediated DA release from AMPH- and saline-pretreated rats. Rats were given repeated saline (triangles) or AMPH (squares) as described in Materials and Methods. DA release from the striatal slices was measured in response to 50 mM KCl (closed symbols) or KRB (open symbols) as described in Materials and Methods and was reported as picomoles of DA per milligram wet weight (ww) ± SEM. A-K⁺ and S-K⁺ represent AMPH (A)- and saline (S)-pretreated rats given a bolus of 50 mM KCl, whereas A-KRB and S-KRB indicate basal DA levels from striatal slices from A- and S-pretreated rats. In comparing the peak K⁺ response, p < 0.03 for A-K⁺ compared with S-K⁺ (Student's t test; n = 6).

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Figure 4. The effect of KN-93 on K⁺-mediated DA release from AMPH- and saline-pretreated rats. Rats were given repeated saline (A) or AMPH (B) as described in Materials and Methods. DA release from the striatal slices was measured in response to 50 mM KCl (closed symbols) or KRB (open symbols) in the absence (squares) or presence (diamonds) of 10 µM KN-93. Results are reported as picomoles of DA per milligram wet weight (ww) ± SEM (n = 3). Statistical analyses were performed using a one-way ANOVA with Tukey-Kramer post hoc analysis on the peak AMPH response, fraction 10. A, ANOVA, p < 0.03; all values for K⁺ differed from those for KRB at p < 0.05. B, ANOVA, p < 0.002; values for K⁺ differed from those for KRB at p < 0.01. In neither A nor B did values with KN-93 (KN93) differ from their respective values without KN-93.

Effect of the CaM kinase II inhibitor on [³H]DA uptake

Because KN-93 could be inhibiting AMPH action by blocking its uptake, we assessed its effect on the uptake of [³H]DA in striatal slices from rats pretreated with saline or AMPH.Experiments were performed in the presence and absence of Ca²⁺ to determine whether there was a Ca²⁺-dependent component of [³H]DA uptake after repeated AMPH. In contrast to the Ca²⁺ dependency of transporter-mediated DA release after repeatedAMPH, striatal DA uptake was Ca²⁺ independent in both AMPH- and saline-pretreated rats (Fig. 5).KN-93 did not significantly affect DA uptake in the striatum fromeither saline- or AMPH-pretreated rats. Nomifensine and GBR-12935,which are dopamine transporter blockers, inhibited [³H]DA uptake into striatal slices equally well from either AMPH-and saline-pretreated animals.

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Figure 5. The effect of Ca²⁺ and KN-93 on [H³]DA uptake in AMPH- and saline-pretreated rats. Striatal slices from saline (light gray)- and AMPH (dark gray)-pretreated rats were incubated as indicated. Values in the left-hand set of bars are those obtained when striata were incubated in KRB lacking CaCl₂. All other samples were incubated in Ca²⁺-containing KRB. [³H]DA uptake was measured as described in Materials and Methods. In some experiments, slices were pretreated for 15 min with 10 µM KN-93, 10 µM nomifensine (NF), or 5 µM GBR-12935 (GBR). The results are expressed as femtomoles of DA per milligram wet weight (ww) of slices. Results represent the average ± SEM of three separate experiments. All values with nomifensine and GBR-12935 differed from values without these drugs at p < 0.05.

Effect of reserpine on AMPH-mediated DA release after repeated AMPH

Although KN-93 had no effect on depolarization-mediated DA release, the Ca²⁺ dependency of both the enhanced AMPH-mediated and the depolarization-mediatedDA release suggested that synaptic vesicles could be involvedin the increased response to both stimuli. To test for a requirementfor synaptic vesicles in the enhanced stimulus-induced DA releaseafter repeated AMPH, we pretreated rats with saline or AMPH andgave the rats reserpine (5 mg/kg, s.c.) or vehicle 9 d after thelast treatment. There were thus four groups of rats differingin repeated treatment and injection type on day 9: saline-pretreatedrats given vehicle on day 9 (Fig. 6, S), saline-pretreated ratsgiven reserpine on day 9 (rS), AMPH-pretreated rats given vehicleon day 9 (A), and AMPH-pretreated rats given reserpine on day9 (rA). Rats were killed the next day, which was day 10 afterthe last drug injection, and DA release in response to eitherAMPH or K⁺ was measured in the striatal slices. The amount of DA releasedin response to 1 µM AMPH is shown in Figure 6A. Reserpine treatmenton day 9 had no effect on endogenous DA release in response to1 µM AMPH in saline-pretreated rats, as we have seen previously(Kantor and Gnegy, 1998). As shown in Figure 6A, reserpine givenon day 9 similarly had no significant effect on AMPH-mediatedDA release in AMPH-pretreated rats. The controls (KRB alone inthe perfusion) for all groups gave the same values and were treatedas one line on Figure 6A to avoid visual clutter. The effect ofreserpine on K⁺-mediated DA release after repeated saline or AMPH is shown inFigure 6B. As expected, reserpine pretreatment abolished K⁺-mediated DA release in slices from rats repeatedly treated witheither saline or AMPH.

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Figure 6. The effect of reserpine on AMPH- and K⁺-mediated DA release in saline- and AMPH-pretreated rats. Rats received repeated saline or AMPH as described in Materials and Methods. On the ninth day after cessation of repeated saline or AMPH, rats were treated with either vehicle or reserpine (5 mg/kg, s.c.) such that four groups were formed: saline-vehicle (S), saline-reserpine (rS), AMPH-vehicle (A), and AMPH-reserpine (rA). Striatal slices were prepared from rats of each group, and DA release was measured in response to AMPH (A), 50 mM KCl (K⁺; B), or continued KRB (basal release; open square). KRB values in A and B comprise the average of basal DA release data from saline, AMPH, and reserpine pretreatment that were all the same. Results are reported as picomoles of DA per milligram wet weight (ww) ± SEM (n = 6). Statistical analyses were performed using a one-way ANOVA with Tukey-Kramer post hoc analysis on the peak AMPH response, fraction 10 (n = 3). A, DA release in response to AMPH (filled symbols) in saline- or AMPH-pretreated rats given vehicle (solid lines) or reserpine (dashed lines) the day before being killed (ANOVA, p < 0.0001). In post hoc Tukey-Kramer analysis, all values differed from KRB at p < 0.01, and all saline pretreatments (S-A and rS-A) differed from all AMPH pretreatments (A-A and rA-A) at p < 0.01. No group with reserpine pretreatment differed from the corresponding group without reserpine pretreatment (S-A vs rS-A) and (A-A vs rA-A). B, DA release in response to K⁺ (filled symbols) in saline- or AMPH-pretreated rats given vehicle (solid lines) or reserpine (dashed lines) the day before being killed (ANOVA, p < 0.0001). In post hoc Tukey-Kramer analysis, values from vehicle-treated rats (S-K⁺ and A-K⁺) differed from KRB values at p < 0.001 and from K⁺ values for reserpine-treated rats at p < 0.01. Values from reserpine-pretreated rats did not differ from KRB values (baseline).

Effect of reserpine treatment on KN-93 inhibition of AMPH-mediated DA release in pretreated rats

To help delineate the site of action of KN-93 in inhibiting striatal AMPH-mediated DA release in AMPH-pretreated rats, weexamined the effect of reserpine on the KN-93 inhibitory action.Because the vesicles were obviously depleted by reserpine (Fig.6B), a lack of effect of KN-93 in reserpine-pretreated rats wouldsuggest that the drug was acting on CaM kinase II on the synapticvesicles. As shown in Figure 2A, 10 µM KN-93 had no effect onAMPH-mediated DA release from saline-pretreated rats. Reserpinegiven on day 9 did not alter that result (Fig. 7A). Similarly,the ability of 10 µM KN-93 to inhibit the enhanced component ofAMPH-mediated DA release in AMPH-pretreated rats was unalteredby reserpine given on day 9 (Fig. 7B). KN-93 (10 µM) did not affectbasal DA levels under any treatment condition.

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Figure 7. The effect of KN-93 on AMPH-mediated DA release in rats treated with reserpine after previous saline and AMPH pretreatment. Rats received repeated injections of saline (A) or AMPH (B) and were treated with reserpine on withdrawal day 9 as described in Materials and Methods and the legend to Figure 6. DA release in striatal slices was measured in response to AMPH (closed symbols) or KRB (open symbols) in the absence (squares) or presence (diamonds) of 10 µM KN-93. Results are reported as picomoles of DA per milligram wet weight (ww) ± SEM (n = 3). Statistical analyses were performed using a one-way ANOVA with Tukey-Kramer post hoc analysis on the peak AMPH response, fraction 10. A, The effect of KN-93 on basal and AMPH (A)-mediated DA release in saline (S)- and reserpine-pretreated rats. ANOVA, p < 0.0001; values with AMPH differed from all values without AMPH at p < 0.001; values with KN-93 (KN93) were no different from that of the comparable control. B, The effect of KN-93 on AMPH-mediated DA release from AMPH- and reserpine-pretreated rats. ANOVA, p < 0.0001; all values with amphetamine were different from those without AMPH at p < 0.01; value for AMPH + KN-93 differed from that for AMPH alone (KN93+A vs A) at p < 0.01.

Protein kinase C inhibitors attenuated AMPH- but not K⁺-stimulated DA release in saline- and AMPH-pretreated rats

We have shown previously that inhibitors of protein kinase C (PKC) completely inhibit AMPH-mediated DA release in the ratstriatum and nucleus accumbens independently of extracellularcalcium (Kantor and Gnegy, 1998; Browman et al., 1999). The specificityof the CaM kinase II inhibition of AMPH-mediated DA release wasexamined by determining whether PKC inhibition attenuated DA releasemediated by AMPH or K⁺ in AMPH-pretreated rats. Striatal slices from rats pretreatedwith saline or AMPH were perfused with 1 µM Ro31-8220 for 30 minbefore the bolus of AMPH or KCl. As shown in Figure 8A, Ro31-8220treatment completely blocked AMPH-mediated DA release in striatalslices from saline-pretreated rats but had only a partial effectin AMPH-pretreated rats (Fig. 8B). On the contrary, Ro31-8220perfusion had no effect on K⁺-stimulated DA release in either saline- or AMPH-pretreated rats.There appeared to be a small degree of inhibition in AMPH-pretreatedrats, but there was no significant difference between K⁺-stimulated values in the absence or presence of Ro31-8220. Whencalculated as fold stimulation over control, the values in AMPH-pretreatedrats for K⁺ and K⁺ + Ro31-8220 samples were 5.9 ± 1.0 and 5.1 ± 1.2, respectively,again showing no significant difference.

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Figure 8. Effect of the PKC inhibitor Ro31-8220 on AMPH- and K⁺-mediated DA release in striatal slices from saline (A)- and AMPH (B)-pretreated rats. Striatal slices were incubated with 1 µM Ro31-8220 for 30 min before being given a 2.5 min bolus of KRB, 1 µM Ro31-8220 (Ro), 1 µM AMPH (A), 1 µM AMPH + 1 µM Ro31-8220 (A+Ro), 50 mM KCl (K), or 50 mM KCl + 1 µM Ro31-8220 (K+Ro). Results are presented as picomoles of DA per milligram wet weight (ww) ± SEM of the peak fraction containing maximal DA (n = 3). A, Effect of Ro31-8220 on DA release in saline-pretreated rats. ANOVA for AMPH-mediated DA release and controls, p < 0.0001. a, In post hoc Tukey-Kramer tests, A differs from KRB, Ro, and A+Ro samples at p < 0.01. ANOVA for K⁺-mediated DA release and controls, p < 0.0001. b, K differs from KRB and Ro samples at p < 0.001. B, Effect of Ro31-8220 on DA release in AMPH-pretreated rats. ANOVA for AMPH-mediated DA release and controls, p < 0.0008. a, In post hoc Tukey-Kramer tests, A differs from KRB and Ro at p < 0.01 and from A+Ro at p < 0.05. ANOVA for K⁺-mediated DA release and controls, p < 0.0003. b, K differs from KRB and Ro at p < 0.001 and from K+Ro at p < 0.01. KRB differs from K+Ro at p < 0.05. c, In comparison of saline pretreatment (A) versus AMPH pretreatment (B), saline-AMPH samples differ from AMPH-AMPH samples at p < 0.02 by Student's t test. d, Saline-K⁺ samples differ from AMPH-K⁺ samples at p < 0.01 by Student's t test.

  DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Our results demonstrate that, after reexposure to AMPH, the striatum from rats treated repeatedly with AMPH displayed a DArelease that was twofold higher than that from saline-treatedrats. The increase in released DA was Ca²⁺ dependent, and the involvement of a Ca²⁺- and CaM-dependent protein phosphorylation was demonstrated bythe ability of KN-93 to inhibit the Ca²⁺-dependent component. Functioning synaptic vesicles seemed notto be integral to the enhanced AMPH-mediated DA release. The twofoldenhancement in K⁺-induced DA release after repeated AMPH, although Ca²⁺ and vesicular dependent, differed from the AMPH-mediated releasein that it was unaffected by KN-93. Similarly, there is a componentof PKC dependence in the AMPH-mediated DA release that is notreflected in K⁺-stimulated DA release. The results concerning AMPH-mediated DArelease correspond to those of Pierce and Kalivas (1997a) who,using microdialysis, demonstrated a Ca²⁺-dependent enhancement in AMPH-induced DA release in the nucleusaccumbens of rats treated repeatedly with cocaine. Ca²⁺ entry into the terminal and activation of Ca²⁺- and CaM-dependent protein kinase activity were crucial to theenhanced AMPH-induced DA release, but exocytosis was not. Consequently,the enhancement in AMPH-induced DA release after repeated AMPHor cocaine may involve similarmechanisms.

Vesicular involvement in enhanced AMPH-mediated DA release

It has been postulated that the enhancement in AMPH-induced release in cocaine- or AMPH-pretreated rats could be caused bya redistribution of DA-containing synaptic vesicles that mightposition them more closely in apposition with plasmalemmal DAtransporters (Robinson, 1991; Pierce and Kalivas, 1997b). "Leakage"or increased transport of DA from the vesicle could serve as thesource of the enhanced DA. In support of that hypothesis, we foundthat repeated AMPH leads to a long-lasting elevation in site 3phosphosynapsin I in rat striatum (Iwata et al., 1996, 1997).Dephosphosynapsin I mediates the formation of ternary complexeswith synaptic vesicle and actin filaments. Phosphorylation ofsynapsin I at sites 2 and 3, substrate sites for CaM kinase II,abolishes those interactions. Because synapsin I is involved inmaintaining a clustered, reserve pool of synaptic vesicles usedduring high synaptic activity (Pieribone et al., 1995), it isconceivable that disruption of this pool could lead to a widerdistribution of vesicles that could enhance the supply of DA tobe released in response to AMPH. Another role for vesicles couldinvolve a direct interaction of AMPH with the vesicular monoaminetransporter VMAT₂ that could increase the availability of DA atthe plasmalemma transporter. Because CaM kinase II is locatedon vesicles, as well as in the cytoplasm (Dunkley et al., 1988;Benfenati et al., 1992), vesicular CaM kinase II could be alteringAMPH action at thevesicles.

Our studies, however, suggest that synaptic vesicles do not provide the source of DA for the enhanced AMPH response afterrepeated AMPH. Reserpine pretreatment completely abolished K⁺-stimulated DA release but did not affect AMPH-stimulated DA releasein the striatum of rats pretreated with either saline or AMPH.In addition, reserpine pretreatment did not alter the abilityof KN-93 to inhibit the Ca²⁺-dependent enhancement in AMPH-induced DA release. Although itis possible that the reserpine treatment did not deplete all ofthe vesicles, one might expect that the responses would have beendiminished if vesicles were strongly involved in these effects.Reserpine completely ablated [³H]tetrabenazine binding to VMAT₂ in rat striatum 1 d after injection,suggesting that vesicles are not functional (Naudon et al., 1995).Therefore, the synaptic vesicles do not seem to be the sourceof the increased DA released by AMPH through the transporter.The possibility that a vesicular CaM kinase II or a vesicularsubstrate for the enzyme is important for the process independentof active VMAT₂ cannot be discounted, however. Our conclusionis predicated on the use of a relative low dose of AMPH, 1 µM,as our challenge dose. There is increasing vesicular involvementin AMPH-mediated DA release as the dose of AMPH is increased (Seidenet al., 1993). Had we used higher doses of AMPH, such as 100 µM,at which vesicles play a prominent role in the amount of DA released(Sulzer et al., 1995), no doubt a vesicular involvement wouldhave been detected. However, we have demonstrated a sensitizedDA release in response to 1 µM AMPH that remained unaltered bypretreatment with reserpine. Therefore the enhanced AMPH-mediatedDA release after repeated AMPH is not dependent on functioningsynapticvesicles.

Role of CaM kinase II in enhanced AMPH-mediated DA release

The most parsimonious conclusion to explain the enhanced AMPH-induced DA release is that intraterminal CaM kinase II activityis maintaining phosphorylation of a substrate that enhances outwardtransport. We demonstrated that CaM kinase II activity is enhancedin striatal synaptosomes after repeated AMPH and that enhancedAMPH-induced DA release can be demonstrated in the synaptosomes(Iwata et al., 1997). The CaM kinase II activity is likely ongoingbecause the inhibitor KN-93 was readily effective. The natureof the substrate is unknown. It could be an ion channel or cytoskeletalprotein affecting transporter function, or it could be the plasmalemmalDA transporter itself. The DA transporter from both rat and humancontains a consensus sequence for CaM kinase II (Giros and Caron,1993). Whatever the substrate, the modification is such that itaffects primarily outward-directed transporter function. Becausethere is no change in basal DA release, the modification is unlikelyto involve a global alteration in ion gradients such as that aninhibition of Na⁺,K⁺-ATPase would provide but could involve an AMPH-mediated effecton an ion gradient. Interestingly, ouabain-stimulated DA releasefrom rat striatum is also enhanced after repeated AMPH (Kanzakiet al., 1992). The modification leading to the enhanced transporter-mediatedDA release did not alter all transporter functions. We and others(Kuczenski and Segal, 1988) have found no change in DA uptakeafter repeated AMPH, showing that inward transport was unaltered.Ca²⁺ did not affect uptake in either saline- or AMPH-pretreated rats.This is in contrast to the report of Uchikawa et al. (1995) whofound that Ca²⁺ and CaM increased [³H]DA uptake in naive rats. We also found that neither Ca²⁺ (data not shown) nor repeated AMPH altered the ability of maximalconcentrations of the uptake blockers nomifensine and GBR-12935to inhibit DA uptake. In microdialysis studies, Pierce and Kalivas(1997a) reported that levels of extraterminal DA in response toGBR-12909 were enhanced after repeated cocaine. This could becaused by the increase in exocytotic, impulse-dependent DA releaseoccurring after repeated AMPH rather than by an altered effectof GBR-12909 on the DAtransporter.

It is possible for a modification to affect outward transport through the plasmalemmal DA transporter without substantivelyaltering inward transport. We found that selective inhibitorsof protein kinase C blocked AMPH-mediated DA release in the striatumand nucleus accumbens from naive animals (Kantor and Gnegy, 1998;Browman et al., 1999) but slightly increased [³H]DA uptake (Kantor and Gnegy, 1998). Although the selective PKCinhibitor Ro31-8220 completely blocked AMPH-mediated DA releasefrom naive (Kantor and Gnegy, 1998; Browman et al., 1999) andsaline-pretreated rats (this study), this inhibitor only partiallyattenuated AMPH-mediated DA release from AMPH-pretreated rats.Inhibition of AMPH-induced DA release by the PKC inhibitors isentirely independent of extracellular calcium (Kantor and Gnegy,1998). Thus the Ca²⁺-sensitive and -insensitive phases of AMPH-induced DA releasein AMPH-pretreated rats seem to be separable and controlled bydifferent protein kinasemechanisms.

Enhanced K⁺-mediated DA release

Repeated AMPH also led to an increase in depolarization-mediated, vesicular-dependent exocytotic release (this study) (Castañedaet al., 1988). Possible explanations for an increase in K⁺-evoked DA release are (1) movement of vesicles from a reserveto a more readily releasable pool, (2) an increase in the numberof vesicles, (3) alteration in a plasmalemmal or vesicular membraneprotein that heightens exocytosis, or (4) altered Ca²⁺ channel activity leading to increased intracellular Ca²⁺. The increase we reported in site 3 phosphosynapsin I (Iwataet al., 1996) could conceivably contribute to an increase in thereadily releasable vesicular pool because it could decrease theattachment of vesicles to a confining cytoskeleton. On the otherhand, KN-93 did not block K⁺-stimulated DA release, suggesting that ongoing Ca²⁺ and CaM protein phosphorylation does not modulate the depolarization-enhancedrelease. It is unlikely that the total number of vesicles increasedbecause we found no change in total synapsin I (Iwata et al.,1996), which seems to be a component of every vesicle, includingdopaminergic vesicles, in the striatum (Greengard et al., 1994).Although the increase in site 3 phosphosynapsin I could contributeto increased exocytotic release of DA, it is unclear whether theincrease is in dopaminergic vesicles. A more probable option isthat there is an increase in Ca²⁺ availability through Ca²⁺ channels that could lead to increased exocytotic release. Ourresults further suggest that ongoing PKC activity is not instrumentalin mediating enhanced K⁺-induced DA release after repeatedAMPH.

Conclusion

We have demonstrated that repeated AMPH treatment leads to an increase in DA released in response to AMPH and K⁺ depolarization. Although the increased DA released in responseto both stimuli was Ca²⁺ dependent, our experiments suggested that a Ca²⁺- and CaM-dependent phosphorylation was critical for the enhancedrelease by AMPH but not for that released by depolarization. Onthe contrary, the depolarization-mediated DA release was entirelyvesicular, whereas vesicles were not required for the AMPH-mediatedrelease. The results suggest that a CaM-dependent phosphorylationof a protein, perhaps the plasmalemma DA transporter itself ora membrane protein affecting the transporter function, could beresponsible for the enhanced AMPH-inducedrelease.

  FOOTNOTES

Received Oct. 29, 1998; revised Feb. 16, 1999; accepted March 9, 1999.

This work was supported by the National Institute on Drug Abuse (NIDA) Grant DA-05066 and NIDA Interdisciplinary TrainingGrant DA-07267 at the University of Michigan Substance Abuse ResearchCenter (L.K.). We thank Terry Robinson for the use of his HPLCand for helpfulconversations.
Correspondence should be addressed to Dr. Margaret E. Gnegy, Department of Pharmacology, 2220E MSRB III, University of MichiganMedical School, Ann Arbor, MI 48109-0634.

  REFERENCES

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

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