Role of Dopamine Transporter in Methamphetamine-Induced Neurotoxicity: Evidence from Mice Lacking the Transporter

QUICK SEARCH:

[advanced]

	Author:		Keyword(s):
Year:		Vol:		Page:

HOME | SEARCH | ARCHIVE | SUBSCRIBE | CONTACT | HELP

This Article

Abstract

Full Text (PDF)

Submit an eLetter

Alert me when this article is cited

Alert me when eLetters are posted

Alert me if a correction is posted

Citation Map

Services

Email this article to a friend

Similar articles in this journal

Similar articles in ISI Web of Science

Similar articles in PubMed

Alert me to new issues of the journal

Download to citation manager

Citing Articles

Citing Articles via HighWire

Citing Articles via ISI Web of Science (94)

Citing Articles via Google Scholar

Google Scholar

Articles by Fumagalli, F.

Articles by Caron, M. G.

Search for Related Content

PubMed

PubMed Citation

Articles by Fumagalli, F.

Articles by Caron, M. G.

Previous Article  |  Next Article

The Journal of Neuroscience, July 1, 1998, 18(13):4861-4869

Role of Dopamine Transporter in Methamphetamine-Induced Neurotoxicity: Evidence from Mice Lacking the Transporter
Fabio Fumagalli, Raul R. Gainetdinov, Kenneth J. Valenzano, and Marc G. Caron
Howard Hughes Medical Institute Laboratories, Department of Cell Biology and Medicine, Duke University Medical Center, Durham, North Carolina 27710

  ABSTRACT

Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

The role of the dopamine transporter (DAT) in mediating the neurotoxic effects of methamphetamine (METH) was tested in micelacking DAT. Dopamine (DA) and serotonin (5-HT) content, glialfibrillary acidic protein (GFAP) expression, and free radicalformation were assessed as markers of METH neurotoxicity in thestriatum and/or hippocampus of wild-type, heterozygote, and homozygote(DAT $-$ / $-$ ) mice. Four injections of METH (15 mg/kg, s.c.), eachgiven 2 hr apart, produced 80 and 30% decreases in striatal DAand 5-HT levels, respectively, in wild-type animals 2 d afteradministration. In addition, GFAP mRNA and protein expressionlevels, extracellular DA levels, and free radical formation wereincreased markedly. Hippocampal 5-HT content was decreased significantlyas well (43%). Conversely, no significant changes were observedin total DA content, GFAP expression, extracellular DA levels,or free radical formation in the striatum of DAT $-$ / $-$ mice afterMETH administration. However, modest decreases were observed instriatal and hippocampal 5-HT levels (10 and 17%, respectively).These observations demonstrate that DAT is required for, and DAis an essential mediator of, METH-induced striatal dopaminergicneurotoxicity, whereas serotonergic deficits are only partiallydependent on DAT.

Key words: dopamine transporter; methamphetamine; microdialysis; serotonin; free radical; GFAP

  INTRODUCTION

Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

Methamphetamine (METH) is a highly abused drug worldwide. This phenylethylamine is a powerful psychostimulant that producesboth addiction and dependence. It is now commonly accepted thatMETH causes neurotoxicity in animals (including nonhuman primates)as clearly shown by the degeneration of monoaminergic systems"in vivo," demonstrating effects on both dopaminergic and serotonergicregions of the CNS. Repeated administration of METH induces long-lastingdeficits in the striatal concentrations of dopamine (DA) and itsmetabolites, tyrosine hydroxylase activity, and dopamine transporter(DAT) binding sites (Gibb and Kogan, 1979; Seiden and Ricaurte,1987; Seiden and Sabol, 1995). Similarly, reductions in forebrainconcentrations of serotonin (5-HT) and its metabolites and thedecrease of tryptophan hydroxylase activity after METH administrationhave been described (Hotchkiss and Gibb, 1980; Ricaurte et al.,1980).

Although several mechanisms have been proposed to explain METH-induced neurotoxicity (Sonsalla et al., 1989; Bowyer et al.,1995; Seiden and Sabol, 1995; Ali et al., 1996; Itzhak and Ali,1996; Ohmori et al., 1996), two hypotheses are considered primarily.First, the ability of the drug to mobilize DA from intraneuronalstores to the extracellular space via DAT-mediated outward transportresults in elevated extracellular DA concentrations. The neurotoxiceffects of METH are postulated to occur from subsequent auto-oxidationof DA to highly reactive free radicals (Seiden and Vosmer, 1984;Axt et al., 1990; Marek et al., 1990a,b). An alternative modelsuggests that redistribution of DA from vesicular storage poolsto the cytoplasmic compartment, allowing intraneuronal oxidation,is the primary cause of DA terminal injury (Cubells et al., 1994).These hypotheses suggest that the balance among vesicular, cytoplasmic,and extracellular DA pools plays a key role in the neurotoxicaction of METH.

Thus DAT, suggested to be critically involved in inward transport of METH with concomitant outward transport of DA (Liangand Rutledge, 1982b), might be an important determinant of METHneurotoxicity. In fact, it has been shown that DA uptake inhibitorssuch as amfonelic acid can selectively antagonize the neurochemicalresponse to METH (Axt et al., 1990; Marek et al., 1990a,b). However,pharmacological manipulations with DA uptake inhibitors do notalways afford complete protection because they depend highly onthe inherent drug properties, route of administration, and dosage.For instance, the DA uptake inhibitor benztropine failed to protectagainst DA depletion after METH challenge (Marek et al., 1990a).Additionally, it has been suggested that the response of the 5-HTsystem to METH treatment is mediated by DA (Hotchkiss and Gibb,1980; Schmidt et al., 1985; Johnson et al., 1987). In this case,amfonelic acid protects 5-HT neurons against METH-induced damage,whereas benztropine does not (Schmidt et al., 1985). These inconsistenciesclearly reveal that pharmacological interventions, although helpful,are limited. To assess the role of DAT in METH-induced neurotoxicitydirectly, we used mice lacking DAT as an in vivo model to determinethe effects of METH on dopaminergic and serotonergic neurons.

  MATERIALS AND METHODS

Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

Animals. The DAT $-$ / $-$ mice were generated as previously described (Giros et al., 1996). Offspring from heterozygote crossingsremained in the same cage until weaning. Mice were genotyped bySouthern blot analysis of tail biopsies as described (Giros etal., 1996). They were separated into different cages accordingto sex and genotype and were maintained under standard housingconditions. Food and water were provided ad libitum. Animal carewas in accordance with the Guide for Care and Use of LaboratoryAnimals (National Institutes of Health publication 865-23, Bethesda,MD) and approved by the Institutional Animal Care and Use Committee.

Drug administration and temperature determination. Three-month-old littermate male wild-type, heterozygote (DAT +/ $-$ ), andhomozygote (DAT $-$ / $-$ ) C57BL/129sVj mice were used in these experiments.METH (Sigma, St. Louis, MO) was dissolved in saline (0.9% NaCl).Four subcutaneous injections of METH (15 mg/kg) or vehicle, eachgiven 2 hr apart, or a single dose of METH (30 mg/kg, s.c.) wasadministered (final injection volume, 10 ml/kg). Rectal body temperatureswere determined by a digital thermometer (Physitemp, Clifton,NJ). The probe was inserted into the rectum and maintained untilthe temperature reading had stabilized. All animal experimentswere approved by the Institutional Animal Care and Use Committee.

Measurement of DA, 5-HT, and metabolites. At 48 hr after the first injection of METH the mice were killed, and striata weredissected from the brain. Dissected striata and hippocampi werehomogenized in 0.1 M perchloric acid containing 100 ng/ml 3,4-dihydroxybenzylamine(DHBA) as an internal standard. Homogenates were centrifuged for10 min at 10,000 × g. Supernatants were filtered through 0.22µm filters and analyzed for levels of DA, 3,4-dihydroxyphenylaceticacid (DOPAC), homovanillic acid (HVA), 5-HT, and 5-hydroxy-indoleaceticacid (5-HIAA), using HPLC with electrochemical detection (HPLC-EC).Monoamines and metabolites were separated on a microbore reversed-phasecolumn (C-18; 5 µm, 1 × 150 mm; Unijet, BAS, West Lafayette, IN)by using a mobile phase consisting of 0.03 M citrate-phosphatebuffer with 2.1 mM octanesulfonic acid, 0.1 mM EDTA, and 17% methanol,pH 3.6, at a flow rate of 90 µl/min that was detected by a 3 mmglassy carbon Unijet electrode (Unijet, BAS) set at +0.85 V (Gainetdinovet al., 1997). The volume of injection was 5 µl.

Determinations of 5-HT synthesis rate in vivo. To measure the rate of 5-HT synthesis, we injected mice simultaneously withthe L-aromatic amino acid decarboxylase inhibitor 3-hydroxybenzylhydrazine(NSD-1015) at 100 mg/kg, intraperitoneally, and saline or METH(30 mg/kg, s.c.) The concentration of 5-hydroxytryptophan (5-HTP)in the striatum 60 min later was determined via HPLC-EC as anin vivo measurement of tryptophan hydroxylase activity (Carlssonet al., 1972). Determinations were performed by using the samecolumn and apparatus as described earlier (Wang et al., 1997)with a mobile phase consisting of (in mM) 50 monobasic sodiumphosphate, 0.2 octyl sodium sulfate, 0.1 EDTA, and 10 NaCl plus10% methanol, pH 2.6. The applied potential was +0.65 V.

RNA preparation and Northern blot analysis. Total RNA from mouse striata was isolated according to Chomczynski and Sacchi(1987). Northern blot analysis was performed according to Fumagalliet al. (1996), using a [³²P]cRNA probe for glial fibrillary acidic protein (GFAP) mRNA.Briefly, after prehybridization, membranes were hybridized overnightat 65°C, washed under high stringency (2× SSC/0.1% SDS for 30min at room temperature, followed by two to three washes in 0.1×SSC/0.1% SDS for 30 min at 68°C), and then exposed to Kodak X-Omatfilms (Rochester, NY). Blots were quantified with a MolecularDynamics PhosphorImager (Sunnyvale, CA) and ImageQuant 3.3 software.A 115 base cRNA probe from a pTRIPLEscript vector (Ambion, Austin,TX) complementary to $beta$ -actin was used as an internal control tocorrect for gel-loading efficiencies.

Immunohistochemistry. At 2 d after METH administration the animals were killed, and the brains were dissected and immersion-fixedin 4% paraformaldehyde in PBS, pH 7.2, overnight at room temperature.Then the brains were dehydrated in ethanol, embedded in paraffin,and cut into 6 µm sections. Neuronal cell bodies were visualizedby routine hematoxylin and eosin staining. Astrocytes were identifiedby immunohistochemistry, using anti-GFAP antibodies (Dako, Carpinteria,CA). Briefly, rehydrated sections were treated with 3% H₂O₂ for10 min to remove endogenous peroxidase activity, rinsed for 20min in PBS, and incubated with nonimmune goat serum (in PBS containing1% BSA) for 20 min before a 60 min incubation with rabbit anti-ratGFAP (1:2000 in 1% PBS/BSA; Dako). Sections then were incubatedwith a secondary IgG antibody (Vectastain Elite ABC immunohistochemistrykit, Vector Laboratories, Burlingame, CA) for 30 min, washed inPBS, incubated in ABC reagent for 30 min, rinsed with PBS, andstained with a DAB substrate containing cobalt ions.

In vivo microdialysis. In vivo microdialysis in freely moving mice was performed as previously described (Gainetdinov et al.,1997). Mice were anesthetized with chloral hydrate (400 mg/kg.,i.p.) and placed in a stereotaxic apparatus. Dialysis probes (2mm membrane length and 0.24 mm outer diameter, Cuprophane; cutoff6000 Daltons, CMA-11, CMA/Microdialysis, Solna, Sweden) with CMA-11guide cannulae were implanted into the right striatum. Becauseof significant differences in animal size (Giros et al., 1996),the stereotaxic coordinates for implantation of microdialysisprobes were anteroposterior (AP) 0.0, dorsoventral (DV) $-$ 4.4,lateral (L) 2.5 for wild-type and DAT +/ $-$ mice; and AP 0.0, DV $-$ 3.2, L 1.8 for DAT $-$ / $-$ mice, relative to bregma (Franklin andPaxinos, 1996). Placement of the probe was verified by subsequenthistological examination.

After surgery the animals were returned to their home cages with free access to food and water. At 24 hr after surgery thedialysis probe was connected to a syringe pump (A-99, Razel ScientificInstruments, Stamford, CT) and perfused at 1 µl/min with artificialCSF [composition (in mM): Na⁺ 150, K⁺ 3.0, Ca²⁺ 1.4, Mg²⁺ 0.8, PO₄ 31.0, and Cl 155, pH 7.3]. After a 1 hr equilibration period the perfusatewas collected every 20 min into tubes containing 1 µl of 2 M perchloricacid. At least four control samples were taken before METH wasadministered. Perfusate samples were assayed for DA, using HPLC-ECby the same chromatographic conditions as those described above.The sensitivity of the method permitted the detection of ~3 fmolof DA.

Analysis of free radical formation. To evaluate the level of free radical formation, we used the "salicylate" microdialysistechnique (Obata and Chiueh, 1992). The microdialysis procedurewas performed as above. For trapping hydroxyl free radicals, thestriatum was perfused with 5 mM sodium salicylate in Ringer'ssolution. Brain dialysate (1 µl/min) was collected every 20 minand assessed immediately for 2,3-dihydroxybenzoic acid (2,3-DHBA)and 2,5-dihydroxybenzoic acid (2,5-DHBA) concentrations by HPLC-ECunder the chromatographic conditions described for 5-HTP measurements.

Data analysis. The data are presented as mean ± SEM and were analyzed statistically by ANOVA with Fisher's Protected Least-SignificantDifference test.

  RESULTS

Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

Effect of METH on DA and 5-HT content in striatum and hippocampus

METH is known to induce profound deficits in both the dopaminergic and serotonergic systems. In this study HPLC-EC was usedto quantitate the effects of METH on the neurochemistry of thesesystems in wild-type, DA transporter knock-out (DAT $-$ / $-$ ), andheterozygous (DAT +/ $-$ ) mice. Four injections of METH (15 mg/kg,s.c, each given 2 hr apart) produced an 80% decrease in DA levelsin the striatum of wild-type animals 2 d after treatment, whereasno diminution was observed in DAT $-$ / $-$ mice (Fig. 1A). In addition,DAT +/ $-$ mice displayed a much smaller decrease in DA levels ascompared with wild-type animals (24%) (Fig. 1A). Similarly, thelevels of DOPAC and HVA, the two main DA metabolites, were decreasedmarkedly in the striatum of wild-type mice (80 and 72%, respectively),moderately reduced in DAT +/ $-$ mice (35 and 28%, respectively),and unchanged in DAT $-$ / $-$ mice (Fig. 1A). These results suggestthat DAT plays a determinant role for striatal dopaminergic neurotoxicity.

View larger version (27K):
[in this window]
[in a new window]
Figure 1. Effect of METH (4 × 15 mg/kg, s.c.) on DA, 5-HT, and metabolite content. A, Striatal levels of DA, DOPAC, and HVA. The data are presented as percentages of striatal monoamine levels in saline-treated controls, which were 18.2 ± 1.6, 1.2 ± 0.1, and 1.5 ± 0.2 ng/mg wet tissue in wild-type mice; 14.2 ± 1.3, 1.0 ± 0.08, and 2.1 ± 0.3 ng/mg wet tissue in DAT +/ $-$ mice; and 0.9 ± 0.05, 0.85 ± 0.1, and 3.9 ± 0.3 ng/mg wet tissue in DAT $-$ / $-$ mice for DA, DOPAC, and HVA, respectively. B, Striatal levels of 5-HT and 5-HIAA. The data are presented as percentages of striatal 5-HT and 5-HIAA levels in saline-treated controls, which were 0.6 ± 0.01 and 0.5 ± 0.08 ng/mg wet tissue in wild-type mice; 0.6 ± 0.02 and 0.5 ± 0.02 ng/mg wet tissue in DAT +/ $-$ mice; and 0.4 ± 0.03 and 0.6 ± 0.05 ng/mg wet tissue in DAT $-$ / $-$ mice for 5-HT and 5-HIAA, respectively. C, Hippocampal levels of 5-HT and 5-HIAA. The data are presented as percentages of hippocampal 5-HT and 5-HIAA levels in saline-treated controls, which were 0.9 ± 0.07 and 0.9 ± 0.11 ng/mg wet tissue in wild-type mice, 0.9 ± 0.07 and 0.9 ± 0.05 ng/mg wet tissue in DAT +/ $-$ mice, and 0.9 ± 0.04 and 1.0 ± 0.1 ng/mg wet tissue in DAT $-$ / $-$ mice for 5-HT and 5-HIAA, respectively. Values represent the mean ± SEM of four to five independent determinations. **p < 0.01 versus controls and *p < 0.05 versus controls.

The serotonergic system also was affected. In striatum, 5-HT levels were decreased by 30% in both wild-type and DAT +/ $-$ mice,whereas DAT $-$ / $-$ mice showed only a 10% decrease that was not statisticallydifferent from control animals (Fig. 1B). In hippocampus, where5-HT levels are higher than in striatum, decreases of 43% in wild-type,31% in DAT +/ $-$ , and 17% in DAT $-$ / $-$ mice were observed (Fig. 1C).The main metabolite of serotonin, 5-HIAA, also was affected. Infact, METH decreased 5-HIAA levels by 36% in the striatum of wild-typemice, with no significant changes in either DAT +/ $-$ or DAT $-$ / $-$ animals (Fig. 1B). Interestingly, in hippocampus, 5-HIAA levelswere diminished not only in wild-type (52%) and DAT +/ $-$ (34%)mice but also in DAT $-$ / $-$ mice (33%) (Fig. 1C). In addition, theactivity of tryptophan hydroxylase, the rate-limiting enzyme of5-HT synthesis, was inhibited markedly in both striatum and hippocampusof wild-type (30 and 38%, respectively) and DAT $-$ / $-$ mice (37 and46%, respectively) (Fig. 2). These data suggest that DAT onlycontributes to, but is not solely responsible for, METH-induced5-HT changes.

View larger version (17K):
[in this window]
[in a new window]
Figure 2. Effect of METH on tryptophan hydroxylase activity. 5-HTP accumulation in the striatum and hippocampus of wild-type and DAT $-$ / $-$ mice 60 min after METH treatment (single injection, 30 mg/kg, s.c.) was used as an indicator of tryptophan hydroxylase activity, as described under Materials and Methods. Concentrations of 5-HTP in saline-treated controls were 0.305 ± 0.043 ng/mg tissue in striatum (n = 5) and 0.697 ± 0.026 ng/mg tissue in hippocampus (n = 8). Values represent the mean ± SEM of five to eight animals per group. **p < 0.01 versus controls and *p < 0.05 versus controls.

It should be noted also that the effects described above were of prolonged duration. Because of a high lethality rate in animalsrepeatedly treated with 15 mg/kg METH, a single injection (30mg/kg) was used to examine its long-term effects in the two genotypes.Serotonergic and dopaminergic indices of METH neurotoxicity werestill apparent in wild-type mice 1 week after treatment with METH(30 mg/kg, s.c.). Dopamine, DOPAC, and HVA levels were reducedin wild-type mice by 80, 45, and 62%, respectively (Fig. 3A),whereas 5-HT and 5-HIAA were depressed by 37 and 26%, respectively(Fig. 3B), as compared with the pretreatment levels. By contrast,no significant changes in DAT $-$ / $-$ mice were observed (Fig. 3A,B).These data suggest that the neurotoxic effects were long-lastingand rule out the possibility that DAT elimination only might havedelayed, and not completely prevented, METH toxicity.

View larger version (20K):
[in this window]
[in a new window]
Figure 3. Long-term effect of METH (single injection, 30 mg/kg, s.c.) on striatal content of DA, DOPAC, and HVA (A) or 5-HT and 5-HIAA (B) in mice killed 7 d after the injection. The data are presented as percentages of striatal monoamine levels in saline-treated controls, which were 18.4 ± 1.0, 1.1 ± 0.1, and 1.6 ± 0.08 ng/mg wet tissue in wild-type mice; and 0.9 ± 0.11, 0.9 ± 0.07, and 3.1 ± 0.06 ng/mg wet tissue in DAT $-$ / $-$ mice for DA, DOPAC, and HVA, respectively. The data are presented as percentages of striatal 5-HT and 5-HIAA levels in saline-treated controls, which were 0.7 ± 0.04 and 0.7 ± 0.02 ng/mg wet tissue in wild-type mice and 0.5 ± 0.03 and 0.6 ± 0.05 ng/mg wet tissue in DAT $-$ / $-$ mice for 5-HT and 5-HIAA, respectively. Values represent the mean ± SEM of five independent determinations. *p < 0.05 versus controls. **p < 0.01 versus controls.

Effect of METH on GFAP gene expression, a marker of neuronal damage

The complete lack of toxic effects of METH in the striatum of DAT $-$ / $-$ mice was demonstrated further by determination of theneuroglial response to the neurotoxin. METH administration isknown to increase GFAP immunoreactivity in the striatum of mice(Pu and Vorhees, 1993). GFAP is a classical marker of astrogliosis(Chiang et al., 1994). In our study Northern blot experimentsshowed a dramatic increase (764%) in GFAP mRNA levels in the striatumof wild-type animals 2 d after METH treatment, whereas no effectwas observed in the DAT $-$ / $-$ mice (Fig. 4A). GFAP mRNA levels inuntreated wild-type and DAT $-$ / $-$ mice were similar, presumablyreflecting the resting state of astrocytes. A similar paradigmwas used to examine the effects of METH in hippocampus. Interestingly,METH treatment did not increase GFAP mRNA levels in the hippocampusof wild-type or DAT $-$ / $-$ animals (data not shown).

View larger version (77K):
[in this window]
[in a new window]
Figure 4. METH-induced astrogliosis. A, Northern blot analysis of GFAP mRNA in striatum of saline- and METH-treated (4 × 15 mg/kg, s.c, each given 2 hr apart) wild-type and DAT $-$ / $-$ mice, killed 2 d after the last injection. Experiments were performed as described under Material and Methods. The blot shown represents a 15 hr exposure. Quantitation of GFAP mRNA expression revealed an eightfold increase in METH-treated wild-type mice, with no significant change in DAT $-$ / $-$ mice (wild-type, 764% ± 179; DAT $-$ / $-$ , 87.5% ± 23.9). Results are expressed as a percentage of saline-injected animals of both genotypes. B, Striatal GFAP immunohistochemical staining. Top panel, METH treatment showing METH-induced astrogliosis in the striatum of wild-type mice. Bottom panel, METH treatment showing no astrogliosis after METH challenge in the striatum of DAT $-$ / $-$ mice. Note the increased number and hypertrophied GFAP-positive astrocytes. The right panels are a higher magnification (40×) of the sections shown on the left.

Astrogliosis was tested further by immunohistochemistry. GFAP immunoreactivity was increased markedly in the striatum of wild-typeanimals (Fig. 4B, top panel), with virtually no staining observedin DAT $-$ / $-$ mice (Fig. 4B, bottom panel). In addition, no increasein GFAP immunoreactivity was observed in the hippocampus of eithergenotype (data not shown). These results confirm and extend ourprevious observations and suggest a strong correlation betweenDAT and METH-induced dopaminergic neurotoxicity in the striatum;moreover, they also indicate that the serotonergic deficits inhippocampus may not be associated with astrogliosis.

Effect of METH on striatal extracellular DA levels

In vivo microdialysis was used to monitor extracellular levels of striatal DA in freely moving wild-type and DAT $-$ / $-$ mice.After the administration of METH (30 mg/kg, s.c.), wild-type animalsshowed an 18-fold increase in extracellular DA, whereas DAT $-$ / $-$ mice showed no significant change (Fig. 5A,). It should be notedthat the extracellular basal level of DA in DAT $-$ / $-$ mice is approximatelyfive times higher (Jones et al., 1998a) than that of wild-typemice [predrug concentrations of DA in dialysates were: wild-type,46.3 ± 18.5 fmol/20 µl (n = 7); DAT $-$ / $-$ , 213.1 ± 68.7 fmol/20µl (n = 5)]. After METH administration the dialysate levels ofDOPAC were decreased by ~60% in both wild-type and DAT $-$ / $-$ mice(Fig. 5B), consistent with METH entering nerve terminals in bothgenotypes and inhibiting monoamine oxidase, one of the known actionsof METH (Seiden et al., 1993).

View larger version (17K):
[in this window]
[in a new window]
Figure 5. Effect of METH (single injection, 30 mg/kg, s.c.) on extracellular levels of striatal DA (A) and DOPAC (B). Microdialysis was used to measure extracellular monoamine levels in freely moving mice, as described under Materials and Methods. Basal concentrations of DOPAC in dialysates were 11.8 ± 2.3 pmol/20 µl in wild-type and 6.8 ±.2.4 pmol/20 µl in DAT $-$ / $-$ mice. Values represent the mean ± SEM of five to seven independent experiments.

Effect of METH on oxygen radical formation in striatum

It has been suggested that METH neurotoxicity depends on the formation of oxygen radicals (De Vito and Wagner, 1989; Cadetet al., 1994; Cubells et al., 1994; Fleckenstein et al., 1997b).In this case the METH-induced increase in intra- and/or extraneuronalDA represents a readily oxidizable pool. With the use of microdialysisand HPLC-EC, the formation of 2,3-DHBA and 2,5-DHBA products generatedby the reaction of oxygen radicals and salicylate (Coudray etal., 1995) were monitored during METH treatment. METH produceda marked increase in DHBA levels in striatum of wild-type mice(three to fourfold), with no significant effect in DAT $-$ / $-$ mice(Fig. 6). These data suggest that an intact DAT-mediated transportis required for the formation of potentially dangerous reactivemolecules that are presumed to drive METH-induced striatal neurotoxicity.

View larger version (18K):
[in this window]
[in a new window]
Figure 6. Effect of METH on oxygen radical concentrations in striatum (single injection, 30 mg/kg, s.c.). 2,5-DHBA (A) and 2,3-DHBA (B) dialysate concentrations were measured during the infusion of 5 mM salicylate through microdialysis probe into the striatum of freely moving mice, as described under Materials and Methods. Values represent the mean ± SEM of four to six experiments.

Effect of METH on body temperature

Several reports have suggested a direct association between METH-induced hyperthermia and dopaminergic neurotoxicity in mice(Bowyer et al., 1992, 1994; Albers and Sonsalla, 1995). To testwhether body temperature plays a role in the lack of effects observedin DAT $-$ / $-$ mice after METH treatment, we measured rectal temperaturein wild-type, DAT +/ $-$ , and DAT $-$ / $-$ mice before and after METHtreatment (30 mg/kg, s.c.). Interestingly, DAT $-$ / $-$ mice had alower basal temperature (35.1°C) when compared with DAT +/ $-$ (36.3°C)and wild-type animals (37.3°C) (Fig. 7). At 1 hr after the injectionof METH, DAT $-$ / $-$ mice showed no increase in body temperature,whereas both wild-type and DAT +/ $-$ mice demonstrated a 2°C elevation(Fig. 7).

View larger version (25K):
[in this window]
[in a new window]
Figure 7. Effect of METH (single injection, 30 mg/kg, s.c.) on body temperature. Temperatures were recorded immediately before and 1 hr after a single injection of METH, as described under Materials and Methods. Values represent the mean ± SEM of eight animals per genotype. **p < 0.001 versus saline-treated wild-type and saline-treated DAT +/ $-$ mice; ^##p < 0.001 versus wild-type saline-treated mice; p < 0.001 versus wild-type and DAT +/ $-$ saline-treated mice.

  DISCUSSION

Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

Repeated administration of METH is thought to produce permanent damage to dopaminergic neurons in the striatum (Wagner etal., 1980; Seiden and Ricaurte, 1987; Ricaurte et al., 1994; Seidenand Sabol, 1995). Although the mechanism of METH neurotoxicityremains controversial, there is strong evidence showing that DAitself acts as a mediator (Gibb and Kogan, 1979; Wagner et al.,1983; Schmidt and Gibb, 1985a; Schmidt et al., 1985; Sonsallaet al., 1986; Marek et al., 1990a; Pu et al., 1994). Thus, thepossibility exists that METH, via interaction with DAT, altersthe homeostasis of the dopaminergic neuron, directly resultingin neurotoxicity.

DAT $-$ / $-$ mice demonstrate a phenotype that highlights the critical role of DAT in the regulation of DA neuron homeostasis.These mice display an overall drastic reduction in tissue DA levelsbut maintain markedly elevated extracellular DA levels (Joneset al., 1998a). Immunohistochemical analysis and binding experimentswere used to assess the DA neuron integrity of DAT $-$ / $-$ mice andrevealed that the nigrostriatal dopaminergic pathways are intactand show no degeneration (Jones et al., 1998a; M. Jaber, unpublisheddata).

The present study directly demonstrates that DAT is required for the dopaminergic neurotoxicity induced by METH, as evidencedby the marked alteration in parameters of dopaminergic cell integrityin wild-type mice and the virtual absence of any changes in DAT $-$ / $-$ mice. Particularly, maintenance of striatal DA and metabolitecontent in DAT $-$ / $-$ mice (see Fig. 1A) strongly suggests a tightlink between functioning DAT and METH-induced neurotoxicity. Inaddition, our experiments show that, although METH dramaticallyincreased GFAP mRNA and protein levels in the striatum of wild-typeanimals, no changes were observed in DAT $-$ / $-$ mice (see Fig. 4A,B),indicating that a complete protection of striatal neurons wasafforded by DAT deletion.

Several mechanisms may underlie the lack of METH toxicity in DAT $-$ / $-$ mice. First, it is known that amphetamines enter cellsthrough DAT and by diffusion (Mack and Bonisch, 1979; Liang andRutledge, 1982a; Zaczek et al., 1991a,b; Seiden et al., 1993;Jones et al., 1998b). Our microdialysis experiments demonstratethat DOPAC was decreased in both wild-type and DAT $-$ / $-$ mice (seeFig. 5), suggesting direct monoamine oxidase (MAO) inhibitionby METH. Hence, access of METH to the cell interior at this dose(30 mg/kg) occurs even in the absence of DAT. This does not ruleout the possibility, however, that a fully active uptake systemmay be required to produce the concentrations of METH necessaryto cause neurotoxicity.

A second mechanism attributed to METH neurotoxicity involves METH displacement of DA from storage vesicles or reversal ofthe vesicular transporter such that cytoplasmic DA levels areenhanced. Indeed, it has been suggested that METH neurotoxicityis mainly attributable to its ability to increase intracellularDA levels (Cubells et al., 1994). Because DAT $-$ / $-$ mice have muchless DA in their vesicular storage pools as compared with wild-typeanimals (Jones et al., 1998a), the possibility exists that DAT $-$ / $-$ mice lack the METH-induced increase in cytoplasmic DA levels,thus explaining the absence of toxicity. Interestingly, Capponet al. (1997) recently demonstrated that postnatal day 20 ratshave fewer DAT binding sites and lower tissue DA content thanadult rats and are resistant to the neurotoxic effects of METH.

A third mechanism may involve the pathway of DA release. For instance, it is known that DA can be released via impulse-dependentvesicular and impulse-independent transporter-mediated release(Raiteri et al., 1979; Hurd and Ungerstedt, 1989). The abilityof amphetamine to release DA appears to occur via the second mechanism(Sulzer et al., 1995). We recently provided evidence that reversetransport by DAT, causing the release of DA from the cytoplasmto the extracellular space, is required for the releasing actionof amphetamine (Jones et al., 1998b). This METH-induced increasein extracellular DA may be a critical component for METH toxicity(Seiden and Vosmer, 1984; Schmidt et al., 1985; Marek et al.,1990b; O'Dell et al., 1992, 1993). Therefore, in DAT $-$ / $-$ micethe absence of transporter may prevent extracellular DA concentrationsfrom rising to neurotoxic levels. Consistent with this hypothesis,microdialysis experiments clearly showed that extracellular DAlevels are elevated dramatically in wild-type animals that areadministered METH, but not in DAT $-$ / $-$ mice. However, it shouldbe noted that, although extracellular steady-state DA levels inDAT $-$ / $-$ mice are fivefold over that of wild-type mice, basal levelsof free radicals are not increased.

Hyperthermia is suggested to be an important contributor of METH-induced neuropathology (Bowyer et al., 1992, 1994; Albersand Sonsalla, 1995). To this end, drugs protecting against METHtoxicity also prevent hyperthermia (Ali et al., 1994; Albers andSonsalla, 1995; Farfel and Seiden, 1995). In contrast, pretreatmentwith reserpine, a drug known to produce hypothermia, does notprevent METH-induced neurotoxicity (Ricaurte et al., 1983; Wagneret al., 1983), suggesting that hyperthermia may contribute to,but is not the sole mediator of, METH toxicity. Interestingly,basal core temperatures were 1 and 2°C lower in DAT +/ $-$ and DAT $-$ / $-$ mice, respectively, as compared with wild-type animals. Hyperthermiaafter METH administration was observed only in wild-type and DAT+/ $-$ mice. However, in DAT +/ $-$ mice, hyperthermia is not paralleledby severe striatal DA depletion as in wild-type mice. Becausethe severity of DA depletion has been correlated with the degreeof hyperthermia (Bowyer et al., 1994), this discrepancy suggeststhat thermal response does not appear to be a primary prerequisitefor METH-induced dopaminergic neurotoxicity; hence, the lack ofhyperthermia in DAT $-$ / $-$ mice does not seem to be sufficient toexplain the lack of toxicity.

Regardless of the mechanisms proposed, it appears that DA-mediated free radical formation is a major contributor to METH-inducedneurotoxicity. Recent evidence demonstrates a correlation betweenoxygen-based radicals and the severity of DA depletion. In fact,pretreatment with antioxidants and the overexpression of superoxidedismutase in transgenic mice both attenuate METH-induced DA depletion(Wagner et al., 1985; De Vito and Wagner, 1989; Cadet et al.,1994). Our data, showing that METH administration leads to themassive production of free radicals in the striatum of wild-typeanimals only, corroborate this view and emphasize the pivotalrole played by DAT in METH-induced neurotoxicity.

In addition to the dopaminergic system, METH also has profound effects on the serotonergic system. Long-lasting modificationshave been observed in several serotonergic markers, includingTPH activity, 5-HT content, and 5-HT transporter levels (Gibbet al., 1994). Moreover, DA has been suggested to play a primaryrole in mediating serotonergic depletion after METH administration.In fact, DA uptake inhibitors greatly improve the deficit in METH-inducedTPH activity (Schmidt et al., 1985). Our data show that the striatalserotonergic system is partially protected in DAT $-$ / $-$ mice, whereasMETH toxicity is clearly evident in both wild-type and DAT +/ $-$ animals, suggesting that striatal serotonergic toxicity may bedependent, at least in part, on free radical formation, giventhe partial protection afforded by DAT deletion. It should bepointed out, however, that striatal 5-HT synthesis is decreasedsignificantly, indicating a direct METH effect on 5-HT neurons.Our results confirm and extend those of Fleckenstein et al. (1997b),which showed that METH treatment in rats leads to a decrease instriatal TPH activity. Conversely, DAT elimination did not protecthippocampal 5-HT neurons against METH toxicity in which both 5-HTand 5-HIAA content were depressed significantly in both wild-typeand DAT $-$ / $-$ mice, suggesting that the action of METH on hippocampalserotonergic neurons is independent of dopaminergic toxicity.Interestingly, the decrease in TPH activity in DAT $-$ / $-$ mice occurswithout an elevation in body temperature. These data do not supportearlier observations from Fleckenstein et al. (1997b), which showedthat hyperthermia contributes to a METH-induced decrease in TPHactivity. However, the greater dose used in our experiments (30vs 15 mg/kg) and the species differences (mice vs rats) potentiallycould explain this difference.

Another important issue is whether METH-induced DA and 5-HT reductions result from direct nerve terminal toxicity or long-termneurotransmitter depletion. A recent study conducted in humansrevealed that METH-induced DA depletion does not necessarily correspondto nerve terminal loss (Wilson et al., 1996). Other authors suggestthat DA decreases after METH might be the result of neuronal downregulationin addition to terminal degeneration (Bowyer et al., 1992, 1994).Interestingly, the depletion of DA storage pools detected in untreatedDAT $-$ / $-$ mice suggests that impairment of DAT-mediated transportresults in decreased intraneuronal accumulation of DA (Jones etal., 1998a). In this case it is important to note that a directmodulatory effect of METH on DAT function has been reported andpresumably is mediated by oxygen radicals (Fleckenstein et al.,1997a,c). Thus, it is reasonable to suggest not only that theneurotoxic effect of METH is mediated by DAT but also that directdepletory action of METH on intraneuronal storage of DA may berelated to plasma membrane transport. The same considerationsmay be extended to the serotonergic system. In our study GFAPmRNA levels were not increased in the hippocampus of wild-typemice, where 5-HT and 5-HIAA levels were found to be decreasedsignificantly, implying a dissociation between 5-HT depletionand astrogliosis. Likewise, Cappon et al. (1997) recently showedthat postnatal day 20 rats that had been administered METH displayed5-HT depletion but not concomitant astrogliosis. Thus, because5-HT depletion persists in DAT $-$ / $-$ mice, METH may affect 5-HTneurons directly without the involvement of dopaminergic mechanisms,and this action presumably occurs via the 5-HT plasma membranetransporter (Schmidt and Gibb, 1985b).

In summary, these results provide direct evidence that an intact and functional DAT is required for the development of METH-induceddopaminergic neurotoxicity; the serotonergic hippocampal deficitsafter METH appears to be independent of dopamine uptake and torely, perhaps, on direct action of the drug on 5-HT neurons.

  FOOTNOTES

Received Jan. 26, 1998; revised April 9, 1998; accepted April 16, 1998.

This work was supported in part by National Institute of Health Grants NS-19576 and MH-40159 and unrestricted gifts from Bristol-MyersSquibb and Zeneca Pharmaceuticals. R.R.G. is a recipient of aTourette Syndrome Association fellowship. We thank Dr. Iain L.Campbell for the generous gift of the GFAP plasmid. We are gratefulto Drs. R. M. Wightman and W. C. Wetsel for critical reading ofthis manuscript. We also thank Dr. A. Bruccoleri and Dr. G. J.Harry for helping with immunohistochemistry and S. Suter and J.A. Holt for excellent technical assistance.
Fabio Fumagalli is a visiting fellow from Center of Neuropharmacology, Institute of Pharmacological Sciences, University ofMilan, Via Balzaretti 9, 20133 Milano, Italy.

Raul R. Gainetdinov is a visiting fellow from the Institute of Pharmacology, Russian Academy of Medical Sciences, Baltiyskaya8, 125315, Moscow, Russia.

Correspondence should be addressed to Dr. Marc G. Caron, Howard Hughes Medical Institute, Box 3287, Duke University MedicalCenter, Durham, NC 27710.

  REFERENCES

Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

Albers DS, Sonsalla PK (1995) Methamphetamine-induced hyperthermia and dopaminergic neurotoxicity in mice: pharmacological profile of protective and nonprotective agents. J Pharmacol Exp Ther 275:1104-1114[Abstract/Free Full Text].
Ali SF, Newport GD, Holson RR, Slikker Jr W, Bowyer JF (1994) Low environmental temperatures or pharmacologic agents that produce hypothermia decrease methamphetamine neurotoxicity in mice. Brain Res 658:33-38[ISI][Medline].
Ali SF, Newport GD, Slikker Jr W (1996) Methamphetamine-induced dopaminergic toxicity in mice. Role of environmental temperature and pharmacological agents. Ann NY Acad Sci 801:187-198[Abstract].
Axt KJ, Commins DL, Vosmer G, Seiden LS (1990) $alpha$ -Methyl-p-tyrosine pretreatment partially prevents methamphetamine-induced endogenous neurotoxin formation. Brain Res 515:269-276[Medline].
Bowyer JF, Tank AW, Newport GD, Slikker Jr W, Ali SF, Holson RR (1992) The influence of environmental temperature on the transient effects of methamphetamine on dopamine levels and dopamine release in striatum. J Pharmacol Exp Ther 260:817-824[Abstract/Free Full Text].
Bowyer JF, Davied DL, Schmued L, Broening HW, Newport GD, Slikker Jr W, Holson RR (1994) Further studies of the role of hyperthermia in methamphetamine neurotoxicity. J Pharmacol Exp Ther 268:1571-1580[Abstract/Free Full Text].
Bowyer JF, Clausing P, Gough B, Slikker Jr W, Holson RR (1995) Nitric oxide regulation of methamphetamine-induced dopamine release in caudate/putamen. Brain Res 699:62-70[ISI][Medline].
Cadet JL, Sheng P, Ali S, Rothman R, Carlson E, Epstein CJ (1994) Attenuation of methamphetamine-induced neurotoxicity in copper/zinc superoxide dismutase transgenic mice. J Neurochem 62:380-383[ISI][Medline].
Cappon GD, Morford LRL, Vorhees CV (1997) Ontogeny of methamphetamine-induced neurotoxicity and associated hyperthermic response. Dev Brain Res 103:155-162[Medline].
Carlsson A, Davis JN, Kehr W, Lindqvist M, Atack CV (1972) Simultaneous measurement of tyrosine and tryptophan hydroxylase activities in brain in vivo using an inhibitor of the aromatic amino acid decarboxylase. Naunyn Schmeidebergs Arch Pharmacol 275:153-168[ISI][Medline].
Chiang CS, Stalder A, Samimi A, Campbell IL (1994) Reactive gliosis as a consequence of interleukin-6 expression in the brain: studies in transgenic mice. Dev Neurosci 16:212-222[ISI][Medline].
Chomczynski P, Sacchi N (1987) Single-step method of RNA isolation by acid guanidinium thiocyanate-phenol-chloroform extraction. Anal Biochem 162:156-159[ISI][Medline].
Coudray C, Talla M, Martin S, Fatome M, Favier A (1995) High-performance liquid-chromatography electrochemical determination of salicylate hydroxylation products as an in vivo marker of oxidative stress. Anal Biochem 227:101-111[ISI][Medline].
Cubells JF, Rayport S, Rajindron G, Sulzer D (1994) Methamphetamine neurotoxicity involves vacuolation of endocytic organelles and dopamine-dependent intracellular stress. J Neurosci 14:2260-2771[Abstract].
De Vito MJ, Wagner GC (1989) Methamphetamine-induced neuronal damage: a possible role for free radicals. Neuropharmacology 28:1145-1150[ISI][Medline].
Farfel GM, Seiden LS (1995) Role of hyperthermia in the mechanism of protection against serotonergic toxicity. II. Experiments with methamphetamine, p-chloroamphetamine, fenfluramine, dizocilpine, and dextromethorphan. J Pharmacol Exp Ther 272:868-875[Abstract/Free Full Text].
Fleckenstein AE, Metzger RR, Gibb JW, Hanson GR (1997a) A rapid and reversible change in dopamine transporters induced by methamphetamine. Eur J Pharmacol 323:R9-R10[Medline].
Fleckenstein AE, Wilkins D, Gibb JW, Hanson GR (1997b) Interaction between hyperthermia and oxygen radical formation in the 5-hydroxytryptaminergic response to a single methamphetamine administration. J Pharmacol Exp Ther 283:281-285[Abstract/Free Full Text].
Fleckenstein AE, Metzger RR, Beyeler ML, Gibb JW, Hanson GR (1997c) Oxygen radicals diminish dopamine transporter function in rat striatum. Eur J Pharmacol 334:111-114[Medline].
Franklin KBJ, Paxinos G (1996) In: The mouse brain in stereotaxic coordinates. San Diego: Academic.
Fumagalli F, Jones SR, Caron MG, Seidler FJ, Slotkin TA (1996) Expression of mRNA coding for the serotonin transporter in aged vs young rat brain: differential effects of glucocorticoids. Brain Res 719:225-228[Medline].
Gainetdinov RR, Fumagalli F, Jones SR, Caron MG (1997) Dopamine transporter is required for in vivo MPTP neurotoxicity: evidence from mice lacking the transporter. J Neurochem 69:1322-1325[ISI][Medline].
Gibb JW, Kogan FJ (1979) Influence of dopamine synthesis on methamphetamine-induced changes in striatal and adrenal tyrosine hydroxylase. Naunyn Schmiedebergs Arch Pharmacol 310:185-187[ISI][Medline].
Gibb JW, Hanson GR, Johnson M (1994) Neurochemical mechanisms of toxicity. In: Amphetamine and its analogs: neuropsychopharmacology, toxicology and abuse (Cho AK, Segal DS, eds), p 269. San Diego: Academic.
Giros B, Jaber M, Jones SR, Wightman RM, Caron MG (1996) Hyperlocomotion and indifference to cocaine and amphetamine in mice lacking the dopamine transporter. Nature 379:606-612[Medline].
Hotchkiss AJ, Gibb JW (1980) Long-term effects of multiple doses of methamphetamine on tryptophane hydroxylase activity in rat brain. J Pharmacol Exp Ther 214:257-262[Abstract/Free Full Text].
Hurd JL, Ungerstedt U (1989) Ca²⁺ dependence of the amphetamine, nomifensine, and Lu 19-005 effect on in vivo dopamine transmission. Eur J Pharmacol 166:261-269[ISI][Medline].
Itzhak Y, Ali SF (1996) The neuronal nitric oxide synthase inhibitor, 7-nitroindazole, protects against methamphetamine-induced neurotoxicity in vivo. J Neurochem 67:1770-1773[ISI][Medline].
Johnson M, Stone DM, Hanson GR, Gibb JW (1987) Role of the dopaminergic nigrostriatal pathway in methamphetamine-induced depression of the neostriatal serotonergic system. Eur J Pharmacol 135:231-234[Medline].
Jones SR, Gainetdinov RR, Jaber M, Giros B, Wightman RM, Caron MG (1998a) Profound neuronal plasticity in response to inactivation of the dopamine transporter. Proc Natl Acad Sci USA 95:4029-4034[Abstract/Free Full Text].
Jones SR, Gainetdinov RR, Wightman RM, Caron MG (1998b) Mechanisms of amphetamine action revealed in mice lacking the dopamine transporter. J Neurosci 18:1979-1986[Abstract/Free Full Text].
Liang NY, Rutledge CO (1982a) Comparison of the release of [³H] dopamine from isolated corpus striatum by amphetamine, fenfluramine, and unlabeled dopamine. Biochem Pharmacol 31:983-992[ISI][Medline].
Liang NY, Rutledge CO (1982b) Evidence for carrier-mediated efflux of dopamine from corpus striatum. Biochem Pharmacol 31:2479-2484[ISI][Medline].
Mack F, Bonisch H (1979) Dissociation constants and lipophicility of catecholamines and related compounds. Naunyn Schmiedebergs Arch Pharmacol 310:1-9[ISI][Medline].
Marek GJ, Vosmer G, Seiden LS (1990a) Dopamine uptake inhibitors block long-term neurotoxic effects of methamphetamine upon dopaminergic neurons. Brain Res 513:274-279[ISI][Medline].
Marek GJ, Vosmer G, Seiden LS (1990b) The effects of monoamine uptake inhibitors and methamphetamine on neostriatal 6-hydroxydopamine (6-OHDA) formation, short-term monoamine depletions, and locomotor activity in the rat. Brain Res 516:1-7[Medline].
Obata T, Chiueh CC (1992) In vivo trapping of hydroxyl free radicals in the striatum utilizing intracranial microdialysis perfusion of salicylate: effects of MPTP, MPDP⁺, and MPP⁺. J Neural Transm 89:139-145[Medline].
O'Dell SJ, Weihmuller FB, Marshall JF (1992) Multiple methamphetamine injections induce marked increases in extracellular striatal dopamine which correlate with subsequent neurotoxicity. Brain Res 564:256-260.
O'Dell SJ, Weihmuller FB, Marshall JF (1993) Methamphetamine-induced DA overflow and injury to striatal DA terminals: attenuation by DA D1 or D2 antagonists. J Neurochem 60:1792-1799[ISI][Medline].
Ohmori T, Abekawa T, Koyama T (1996) The role of glutamate in the neurotoxic effects of methamphetamine. Ann NY Acad Sci 801:315-326[Medline].
Pu C, Vorhees CV (1993) Developmental dissociation of methamphetamine-induced depletion of dopaminergic terminals and astrocyte reaction in rat striatum. Dev Brain Res 72:325-328[Medline].
Pu C, Fisher JE, Cappon GD, Vorhees CV (1994) The effects of amfonelic acid, a dopamine uptake inhibitor, on methamphetamine-induced dopaminergic terminal degeneration and astrocytic response in rat striatum. Brain Res 649:217-224[ISI][Medline].
Raiteri M, Cerrito F, Cervoni AM, Levi G (1979) Dopamine can be released by two mechanisms differentially affected by the dopamine transport inhibitor nomifensine. J Pharmacol Exp Ther 208:195-202[Free Full Text].
Ricaurte GA, Schuster CR, Seiden LS (1980) Long-term effects of repeated methylamphetamine administration on dopamine and serotonin neurons in the rat brain: a regional study. Brain Res 193:153-163[ISI][Medline].
Ricaurte GA, Fuller RW, Perry KW, Seiden LS, Schuster CR (1983) Fluoxetine increases long-lasting neostriatal dopamine depletion after administration of D-metamphetamine and D-amphetamine. Neuropharmacology 22:1165-1169[ISI][Medline].
Ricaurte GA, Sabol KE, Seiden LS (1994) Functional consequences of neurotoxic amphetamine exposure. In: Amphetamine and its analogs: neuropsychopharmacology, toxicology and abuse (Cho AK, Segal DS, eds), pp 297-313. Orlando, FL: Academic.
Schmidt CJ, Gibb JW (1985a) Role of the dopamine uptake carrier in the neurochemical response to methamphetamine: effects of amfonelic acid. Eur J Pharmacol 109:73-80[Medline].
Schmidt CJ, Gibb JW (1985b) Role of the serotonin uptake carrier in the neurochemical response to methamphetamine: effects of citalopram and chlorimipramine. Neurochem Res 10:637-648[Medline].
Schmidt CJ, Ritter JK, Sonsalla PK, Hanson GR, Gibb JW (1985) Role of dopamine in the neurotoxic effects of methamphetamine. J Pharmacol Exp Ther 233:539-544[Abstract/Free Full Text].
Seiden LS, Ricaurte G (1987) Neurotoxicity of methamphetamine and related drugs. In: Psychopharmacology: the third generation of progress (Meltzer HY, ed), pp 359-365. New York: Raven.
Seiden LS, Sabol KE (1995) Neurotoxicity of methamphetamine-related drugs and cocaine. In: Handbook of neurotoxicology (Chang LW, Dyer RS, eds), pp 825-843. New York: Dekker.
Seiden LS, Vosmer G (1984) Formation of 6-hydroxydopamine in caudate nucleus of the rat brain after a single large dose of methylamphetamine. Pharmacol Biochem Behav 21:29-31[ISI][Medline].
Seiden LS, Sabol KE, Ricaurte GA (1993) Amphetamine: effects on catecholamine systems and behavior. Annu Rev Pharmacol Toxicol 32:639-677.
Sonsalla PK, Gibb JW, Hanson GR (1986) Roles of D1 and D2 dopamine receptor subtypes in mediating the methamphetamine-induced changes in monoamine systems. J Pharmacol Exp Ther 238:932-937[Abstract/Free Full Text].
Sonsalla PK, Nicklas WJ, Heikkila RE (1989) Role for excitatory amino acids in methamphetamine-induced nigrostriatal dopaminergic toxicity. Science 243:398-400[Abstract/Free Full Text].
Sulzer D, Chen TK, Lau YY, Kristensen H, Rayport S, Ewing A (1995) Amphetamine redistributes dopamine from synaptic vesicles to the cytosol and promotes reverse transport. J Neurosci 15:4102-4108[Abstract].
Wagner GC, Ricaurte G, Seiden LS, Schuster CR, Miller RJ, Westley J (1980) Long-lasting depletions of striatal dopamine and loss of dopamine uptake sites following repeated administration of methamphetamine. Brain Res 181:151-160[ISI][Medline].
Wagner GC, Lucot JB, Schuster CR, Seiden LS (1983) $alpha$ -Methyltyrosine attenuates and reserpine increases methamphetamine-induced neuronal changes. Brain Res 270:285-288[ISI][Medline].
Wagner GC, Carelli RM, Jarvis MF (1985) Pretreatment with ascorbic acid attenuates the neurotoxic effects of methamphetamine in rats. Res Commun Chem Pathol Pharmacol 47:221-228[Medline].
Wang YM, Gainetdinov RR, Fumagalli F, Xu F, Jones SR, Bock CB, Miller GW, Wightman RM, Caron MG (1997) Knock-out of the vesicular monoamine transporter-2 gene results in neonatal death and supersensitivity to cocaine and amphetamine. Neuron 19:1285-1296.
Wilson JM, Kalasinsky KS, Levey AI, Bergeron C, Reiber G, Anthony RM, Schmunk GA, Shannak K, Haycock JW, Kish SJ (1996) Striatal dopamine nerve terminal markers in human, chronic methamphetamine users. Nat Med 2:699-703[ISI][Medline].
Zaczek R, Culp S, De Souza EB (1991a) Interactions of [³H]amphetamine with rat brain synaptosomes. II. Active transport. J Pharmacol Exp Ther 257:830-835[Abstract/Free Full Text].
Zaczek R, Culp S, Goldberg H, McCann DJ, De Souza EB (1991b) Interactions of [³H]amphetamine with rat brain synaptosomes. I. Saturable sequestration. J Pharmacol Exp Ther 257:820-829[Abstract/Free Full Text].

Copyright © 1998 Society for Neuroscience 0270-6474/98/18134861-09$05.00/0

This article has been cited by other articles:

D. Matsuzawa, K. Hashimoto, R. Miyatake, Y. Shirayama, E. Shimizu, K. Maeda, Y. Suzuki, Y. Mashimo, Y. Sekine, T. Inada, et al.
Identification of Functional Polymorphisms in the Promoter Region of the Human PICK1 Gene and Their Association With Methamphetamine Psychosis
Am J Psychiatry, July 1, 2007; 164(7): 1105 - 1114.
[Abstract] [Full Text] [PDF]

M. Cyr, T. D. Sotnikova, R. R. Gainetdinov, and M. G. Caron
Dopamine enhances motor and neuropathological consequences of polyglutamine expanded h