In Vivo Electrochemical Studies of Dopamine Clearance in the Rat Substantia Nigra: Effects of Locally Applied Uptake Inhibitors and Unilateral 6-Hydroxydopamine Lesions

Abstract: High-speed chronoamperometric recordings were used to measure the uptake and clearance of locally applied dopamine (DA) within the substantia nigra (SN) of anesthetized rats. To establish that DA clearance within the SN was mediated primarily by the DA transporter (DAT) rather than the norepinephrine transporter (NET) or the serotonin transporter (SERT), we locally applied uptake inhibitors with different selectivity profiles for the various amine transporters. Nomifensine, a DAT/NET inhibitor, significantly potentiated both the amplitude and the time course of the DA signals. In contrast, neither the selective NET inhibitor desipramine, nor the selective SERT inhibitor citalopram affected the DA signal, suggesting that NET and SERT do not contribute to DA uptake and clearance within the regions of the SN studied over the concentration ranges (1–5 µ M ) used. In unilaterally 6-hydroxydopamine-lesioned rats, the time course of the DA signal was increased in both the lesioned SN and striatum, relative to the unlesioned hemisphere, indicating loss of DAT and decreased DA uptake and clearance. In addition, when identical amounts of DA were injected in the striatum and SN, peak signal amplitudes were larger in the SN, suggesting that the amplitudes are related to the number of DAT sites in a given region of brain tissue. For signals of equivalent amplitudes, clearance rates were lower in the SN than in the striatum, consistent with a lower capacity for DAT-mediated DA uptake within the SN. These results suggest that the DAT is the major transporter responsible for DA clearance within the rat SN.     

d-Fenfluramine Increases Striatal Extracellular Dopamine In Vivo Independently of Serotonergic Terminals or Dopamine Uptake Sites

Abstract: The effect of various doses of the serotonin (5-HT) release-inducing agent d -fenfluramine ( d -fenf) on extracellular dopamine (DA), 3,4-dihydroxyphenylacetic acid (DOPAC), and 5-hydroxyindoleacetic acid (5-HIAA) was studied in vivo in the striatum of halothane-anesthetized rats, following systemic and local administration. At 5 and 10 but not 2.5 mg/kg, d -fenf administered intraperitoneally significantly increased DA extracellular concentration and reduced DOPAC outflow. A concentration-dependent enhancement of DA dialysate content was also found following intrastriatal application (5, 10, 25, and 50 µ M ). The bilateral administration of 5,7-dihydroxytryptamine into the dorsal raphe nucleus, which markedly depleted 5-HT in the striatum, did not modify the effect on extracellular DA concentration of 25 µ M d -fenf locally applied into the striatum. The enhancement of extracellular DA level induced by 25 µ M d -fenf was slightly but significantly reduced by the local application of 25 µ M citalopgram. The blockade of DA uptake sites by nomifensine (0.1, 0.3, and 1 µ M ) did not modify significantly the effect of d -fenf. The rise of DA outflow induced by 25 µ M d -fenf was strongly reduced in the presence of 1 µ M tetrodotoxin (TTX) or by the removal of Ca²⁺ from the perfusion medium. The results obtained show that d -fenf increases the striatal extracellular DA concentration by a Ca²⁺-dependent and TTX-sensitive mechanism that is independent of striatal 5-HT itself or DA uptake sites.     

In Vivo Electrochemical Studies of Dopamine Overflow and Clearance in the Striatum of Normal and MPTP-Treated Rhesus Monkeys

Abstract: Rapid chronoamperometric recordings, using Nafion-coated carbon-fiber electrodes (30–90 µm o.d.), were used to investigate overflow and uptake of dopamine (DA) in the striatum of normal and 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP)-treated rhesus monkeys. The monkeys were anesthetized with isoflurane and placed in a stereotaxic apparatus. Magnetic resonance imaging-guided sterile stereotaxic procedures were used for implantations of the electrochemical electrodes coupled with single-barrel micropipettes that were used to apply potassium or DA locally. Potassium evoked a robust overflow of DA-like electrochemical signals into the brain extracellular space in the unlesioned or normal putamen and caudate nucleus of the rhesus monkeys. In contrast, potassium did not produce any detectable changes (> 97% depletion) of DA in the MPTP-lesioned striatum. In addition, the diffusion/clearance of locally applied DA was markedly altered in the lesioned caudate nucleus and putamen compared with unlesioned striatum. Cell counts of the number of residual tyrosine hydroxylase-positive neurons in MPTP-treated monkeys, in conjunction with whole-tissue levels of DA and its metabolites, showed that the MPTP lesions produced extensive damage of the nigrostriatal DA system. These data indicate that residual dopaminergic fibers remaining after MPTP lesions are dysfunctional and have a greatly diminished capacity for high-affinity DA uptake.     

Putative cocaine receptor in striatum is a glycoprotein with active thiol function

Dopamine transporters of bovine and rat striata were identified by their specific [3H]cocaine binding and cocaine-sensitive [3H]dopamine [( 3H]DA) uptake. Both binding and uptake functions of bovine striatal transporters were potentiated by lectins. Concanavalin A (Con A) increased the velocity but did not change the affinity of the transporter for DA; however, it increased its affinity for cocaine without changing the number of binding sites. This suggests that the DA transporter is a glycoprotein and that Con A action on it produces conformational changes. Inorganic and organic mercury reagents inhibited both [3H]DA uptake and [3H]cocaine binding, though they were all more potent inhibitors of the former. n-Ethylmaleimide inhibited [3H]DA uptake totally but [3H]cocaine binding only partially. Also, n-pyrene maleimide had differential effects on uptake and binding, inhibiting uptake and potentiating binding. [3H]DA uptake was not affected by mercaptoethanol up to 100 mM, whereas [3H]cocaine binding was inhibited by concentrations above 10 mM. On the other hand, both uptake and binding were fairly sensitive to dimercaprol (less than 1 mM). The effects of all these sulfhydryl reagents suggest that the DA transporter has one or more thiol group(s) important for both binding and uptake activities. The Ellman reagent and dithiopyridine were effective inhibitors of uptake and binding only at fairly high concentration (greater than 10 mM). Loss of activity after treatment with the dithio reagents may be a result of reduction of a disulfide bond, which may affect the transporter conformation.     

Cocaine increases dopamine uptake and cell surface expression of dopamine transporters

In HEK 293 cells expressing the human dopamine transporter (DAT), a 10-min incubation with 10 microM cocaine followed by extensive washing resulted in a 30% increase in [3H]dopamine (DA) uptake as well as an increase in cell surface DAT in biotinylation experiments. Consistent with this novel regulation, [3H]DA uptake into synaptosomes prepared from the nucleus accumbens of rats sacrificed 30 min after a single cocaine injection (30 mg/kg) was significantly increased compared to controls (56% increase in V(max), no change in K(m)). In addition, DA clearance in the striatum of anesthetized rats was increased after local application of a low (3 pmol) but not high (65 pmol) dose of cocaine, presumably as a result of mobilization of DAT to the cell surface. Cocaine-induced increases in cell surface expression of DAT and associated changes in DA clearance represent a novel mechanism that may play a role in its addictive properties.     

High affinity stereospecific binding of [3H] cocaine in striatum and its relationship to the dopamine transporter

A high affinity (KD 35 nM) binding site for [3H]cocaine is detected in rat brain striatum present at 2-3 pmol/mg protein of synaptic membranes. This binding is displaced by cocaine analogues with the same rank order as their inhibition of [3H]dopamine ([3H]DA) uptake into striatal synaptosomes (r = 0.99), paralleling the order of their central stimulant activity. The potent DA uptake inhibitors nomifensine, mazindol, and benztropine are more potent inhibitors of this high affinity [3H]cocaine binding than desipramine and imipramine. Cathinone and amphetamine, which are more potent central stimulants than cocaine, displace the high affinity [3H]cocaine binding stereospecifically, but with lower potency (IC50 approximately equal to 1 microM) than does cocaine. It is suggested that the DA transporter in striatum is the putative "cocaine receptor." Binding of [3H]cocaine, measured in 10 mM Na2HPO4-0.32 M sucrose, pH 7.4 buffer, is inhibited by physiologic concentrations of Na+ and K+ and by biogenic amines. DA and Na+ reduce the affinity of the putative "cocaine receptor" for [3H]cocaine without changing the Bmax, suggesting that inhibition may be competitive. However, TRIS reduces [3H]cocaine binding noncompetitively while Na+ potentiates it in TRIS buffer. Binding of [3H]mazindol is inhibited competitively by cocaine. In phosphate-sucrose buffer, cocaine and mazindol are equally potent in inhibiting [3H]mazindol binding, but in TRIS-NaCl buffer cocaine has 10 times lower potency. It is suggested that the cocaine receptor in the striatum may be an allosteric protein with mazindol and cocaine binding to overlapping sites, while Na+ and DA are allosteric modulators, which stabilize a lower affinity state for cocaine.     

Extracellular Concentrations of Cocaine and Dopamine Are Enhanced During Chronic Cocaine Administration

Chronic cocaine administration produces significant increases in cocaine-induced locomotor activity and stereotypy. In vivo microdialysis procedures were used to monitor extracellular dopamine (DA) and cocaine concentrations in the nucleus accumbens (N ACC) and cocaine concentrations in plasma of animals that received chronic or acute cocaine treatments. Following a cocaine challenge injection, concentrations of both cocaine and DA increased to significantly higher levels over time in animals that had received daily cocaine injections for 10 or 30 days than in control animals that received daily injections of saline. Concentrations of cocaine and DA in the N ACC reached maximum levels in the first 30 min following a challenge injection of cocaine. The maximum cocaine concentrations of 10- and 30-day chronic animals were, respectively, 186% and 156%, whereas the maximum DA concentrations were 264% and 216% above the maximum values observed in acute control animals. The results indicate that reverse tolerance effects observed following chronic cocaine administration may in part be accounted for by increased cocaine concentrations. Furthermore, chronic cocaine administration (over a 10- or 30-day period) increased the concentration of cocaine detected in plasma above control levels following a challenge injection. The increase in brain concentrations of cocaine in chronic animals is apparently due to increased concentrations of cocaine in plasma. A physiological change occurs in the periphery as a result of chronic cocaine administration that increases cocaine concentrations in plasma, increases extracellular cocaine levels in the brain, and increases the extracellular concentration of DA in the N ACC.     

Clearance of Exogenous Dopamine in Rat Dorsal Striatum and Nucleus Accumbens: Role of Metabolism and Effects of Locally Applied Uptake Inhibitors

In vivo electrochemistry was used to investigate the mechanisms contributing to the clearance of locally applied dopamine in the dorsal striatum and nucleus accumbens of urethane-anesthetized rats. Chronoamperometric recordings were continuously made at 5 Hz using Nafion-coated carbon fiber electrodes. When a finite amount of dopamine was pressure-ejected at 5-min intervals from a micropipette adjacent to the electrode, transient and reproducible dopamine signals were detected. Substitution of L-a-methyldopamine, a substrate for the dopamine transporter but not for monoamine oxidase, for dopamine in the micropipette did not substantially alter the time course of the resulting signals. This indicates that metabolism of locally applied dopamine to 3,4-dihydroxyphenylacetic acid is not responsible for the decline in the dopamine signal. Similarly, changing the applied oxidation potential from ±0.45 to ±0.80 V, which allows for detection of 3-methoxytyramine formed from dopamine via catechol-O-methyltransferase, had little effect on signal amplitude or time course. In contrast, lesioning the dopamine terminals with 6-hydroxydopamine, or locally applying the dopamine uptake inhibitors cocaine or nomifensine before pressure ejection of dopamine, significantly increased the amplitude and time course of the dopamine signals in both regions. The effects of cocaine and nomifensine were greater in the nucleus accumbens than in the dorsal striatum. Local application of lidocaine and procaine had no effect on the dopamine signals. Initial attempts at modeling resulted in curves that were in qualitative agreement with our experimental findings. Taken together, these data indicate that (1) uptake of dopamine by the neuronal dopamine transporter, rather than metabolism or diffusion, is the major mechanism for clearing locally applied dopamine from the extracellular milieu of the dorsal striatum and nucleus accumbens, and (2) the nucleus accumbens is more sensitive to the effects of inhibitors of dopamine uptake than is the dorsal striatum.     

The role of conserved tryptophan and acidic residues in the human dopamine transporter as characterized by site-directed mutagenesis

The human dopamine (DA) transporter (hDAT) contains multiple tryptophans and acidic residues that are completely or highly conserved among Na(+)/Cl(-)-dependent transporters. We have explored the roles of these residues using non-conservative substitution. Four of 17 mutants (E117Q, W132L, W177L and W184L) lacked plasma membrane immunostaining and were not functional. Both DA uptake and cocaine analog (i.e. 2beta-carbomethoxy-3beta-(4-fluorophenyl)tropane, CFT) binding were abolished in W63L and severely damaged in W311L. Four of five aspartate mutations (D68N, D313N, D345N and D436N) shifted the relative selectivity of the hDAT for cocaine analogs and DA by 10-24-fold. In particular, mutation of D345 in the third intracellular loop still allowed considerable [(3)H]DA uptake, but caused undetectable [(3)H]CFT binding. Upon anti-C-terminal-hDAT immunoblotting, D345N appeared as broad bands of 66-97 kDa, but this band could not be photoaffinity labeled with cocaine analog [(125)I]-3beta-(p-chlorophenyl)tropane-2beta-carboxylic acid ([(125)I]RTI-82). Unexpectedly, in this mutant, cocaine-like drugs remained potent inhibitors of [(3)H]DA uptake. CFT solely raised the K(m) of [(3)H]DA uptake in wild-type hDAT, but increased K(m) and decreased V(max) in D345N, suggesting different mechanisms of inhibition. The data taken together indicate that mutation of conserved tryptophans or acidic residues in the hDAT greatly impacts ligand recognition and substrate transport. Additionally, binding of cocaine to the transporter may not be the only way by which cocaine analogs inhibit DA uptake.     

The Transport Systems for Selenomethionine/Methionine and Selenocystine/Cystine in Escherichia Coli K-12 Appear to be Cooperative

Dopamine transporters of bovine and rat striata were identified by their specific [³H]cocaine binding and cocaine-sensitive [³H]dopamine ([³H]DA) uptake. Both binding and uptake functions of bovine striatal transporters were potentiated by lectins. Concanavalin A (Con A) increased the velocity but did not change the affinity of the transporter for DA; however, it increased its affinity for cocaine without changing the number of binding sites. This suggests that the DA transporter is a glycoprotein and that Con A action on it produces conformational changes

Inorganic and organic mercury reagents inhibited both [³H]DA uptake and [³H]cocaine binding, though they were all more potent inhibitors of the former, n- Ethylmaleimide inhibited [³H]DA uptake totally but [³H]cocaine binding only partially. Also, n-pyrene maleimide had differential effects on uptake and binding, inhibiting uptake and potentiating binding. [³H]DA uptake was not affected by mercaptoethanol up to 100 mM, whereas [³H]cocaine binding was inhibited by concentrations above 10 mM. On the other hand, both uptake and binding were fairly sensitive to dimercaprol (< 1 mM). The effects of all these sulfhydryl reagents suggest that the DA transporter has one or more thiol group(s) important for both binding and uptake activities. The Ellman reagent and dithiopyridine were effective inhibitors of uptake and binding only at fairly high concentration (>10 mM). Loss of activity after treatment with the dithio reagents may be a result of reduction of a disulfide bond, which may affect the transporter conformation     

Distinct temperature-dependent dopamine-releasing effect of drugs of abuse in the olfactory bulb

It was recently shown in the olfactory bulb (OB) that the response to olfactory stimulation might be related to local reinforcement mechanisms involved in discrimination of different odors. Therefore, it seemed interesting to study the effects of several drugs of abuse on the release of dopamine (DA) in the OB. Nicotine, amphetamine, 3,4-methylenedioxymethamphetamine (MDMA, "ecstasy"), and cocaine at 37 degrees C increased the release of [3H] DA from olfactory bulb slice preparations of the rats. While nicotine, amphetamine, and MDMA directly evoked DA release, cocaine, by inhibiting the reuptake processes, enhanced the electrical stimulation-evoked release. At low temperature (17 degrees C), a condition in which the transmitter uptake carriers of the plasma membrane in both the normal and reverse mode of operation are inhibited, the nicotine-evoked [3H] DA release was potentiated, whereas those evoked by amphetamine and MDMA were inhibited. At low temperature the field stimulation-evoked [3H] DA release was potentiated, but under this condition cocaine failed to increase the release. Our results show that low temperature (a) increases the concentration of extracellular DA released by Ca(2+)-dependent vesicular exocytosis elicited by nicotine, (b) inhibits the extracellular Ca(2+)-independent amphetamine- and MDMA-induced release of DA that occurs by the reverse operation of membrane carriers transporting DA from the cytoplasm of presynaptic terminals to the extraneuronal space, and (c) does not alter the inhibitory effect of cocaine on DA uptake that increases the concentration of extracellular DA released by field stimulation. The findings that the drugs of abuse tested all enhanced the release of DA in the olfactory bulb suggest that local reinforcing mechanisms may also exist in this brain area. In addition, we also show that lowering the temperature in in vitro experiments is an easy and straightforward method for separating vesicular and cytoplasmic release of transmitters, and is suitable for studying the mechanism of catecholamine release evoked by drugs of abuse. This technique may be applicable in other neurochemical studies that need inhibition of the uptake carriers without the blockade of the ligand-gated ion channels caused by reuptake inhibitor drugs.     

Differential regulation of accumbal dopamine transmission in rats following cocaine, heroin and speedball self-administration

Cocaine/heroin combinations (speedball) exert synergistic neurochemical and behavioral effects that are thought to contribute to the increased abuse potential and subjective effects reported by polydrug users. In vivo fast-scan cyclic voltammetry was used to examine the effects of chronic intravenous self-administration (25 consecutive sessions) of cocaine (250 μg/inf), heroin (4.95 μg/inf) and speedball (250/4.95 μg/inf cocaine/heroin) on changes in electrically evoked dopamine (DA) efflux, maximal rate of DA uptake (V(max)) and the apparent affinity (K(m)) of the DA transporter in the nucleus accumbens. The increase in electrically evoked DA was comparable following cocaine and speedball injection; however, heroin did not increase evoked DA. DA transporter K(m) values were similarly elevated following cocaine and speedball, but unaffected by heroin. However, speedball self-administration significantly increased baseline V(max), while heroin and cocaine did not change baseline V(max), compared with the baseline V(max) values of drug-na?ve animals. Overall, elevated DA clearance is a likely consequence of synergistic elevations of nucleus accumbens extracellular DA concentrations by chronic speedball self-administration, as reported previously in microdialysis studies. The present results indicate neuroadaptive processes that are unique to cocaine/heroin combinations and cannot be readily explained by simple additivity of changes observed with cocaine and heroin alone.     

A review of the effects of dopaminergic agents on humans,animals, and drug-seeking behavior,and its implications for medication development

Medication development for cocaine abuse has focused on potential mechanisms of action related to the abuse of cocaine. The hypothesis that mesolimbic dopamine (DA) is the key neurochemical mediator of cocaine’s addictive and reinforcing effects is well supported by a wide variety of data from animal studies. On the other hand, medications that increase DA or block its actions in humans can produce effects that appear incompatible with this hypothesis. This article reviews these incompatibilities between animal and human data with a focus on the DAergic actions of drugs, including DA reuptake inhibitors, direct DA agonists, DA increasers, and DA antagonists. Possible reasons for these discrepancies are discussed, and the potential role of high-affinity DA uptake inhibitors, such as GBR12909, for pharmacotherapeutic application to treat cocaine abuse is discussed. Since progress in developing pharmacotherapies for treating cocaine addiction in humans is likely to come from understanding its mechanisms of action, it is clear that further research on the effects of cocaine in humans and animals will be critical to the medication development effort. A shortened version of this paper was presented at the Satellite Meeting of the International Society for Neurochemistry on “Cellular and Molecular Mechanisms of Drugs of Abuse: Cocaine and Methamphetamine” held on August 19–20, 1993 in Nice, France.     

Aspartate 345 of the dopamine transporter is critical for conformational changes in substrate translocation and cocaine binding

The present study elucidated the role of aspartate 345, a residue conserved in the third intracellular loop of all Na+/Cl(-)-dependent neurotransmitter transporters, in conformational changes of the dopamine (DA) transporter. Asparagine substitution (D345N) resulted in near normal transporter expression on the cell surface but caused extremely low Vmax and Km values for DA uptake, converted the inhibitory effect of Zn2+ on DA uptake to a stimulatory one, and eliminated reverse transport. The cocaine-like inhibitor 2beta-carbomethoxy-3beta-(4-fluorophenyl)tropane or the selective DA transporter inhibitor GBR12935 bound to D345N with a normal affinity and still inhibited DA uptake potently. However, the mutation reduced the binding capacity of the surface transporter for these two inhibitors by 90% or more. Moreover, the binding activity of D345N can be significantly improved by Zn2+ but not by Na+. These results are consistent with a defect in reorientation of the substrate-binding site to the extracellular side, leading to a loss of the outward-facing conformational state where external DA binds to initiate uptake and the inhibitors bind to initiate uptake inhibition. Alanine or glutamate substitution produced a similar phenotype, suggesting that both the negative charge and the residue volume at position 345 are vital. Furthermore, in intact cells, cocaine potentiated the reaction of the membrane-impermeant sulfhydryl reagent methanethiosulfonate ethyltrimethylammonium with the extracellularly located endogenous cysteines of D345N but not those of wild type, and this potentiation was blocked upon K+ substitution for Na+. Thus, cocaine binding to D345N likely induces a different and Na(+)-dependent conformational change, which may contribute to its Na(+)-dependent uptake inhibitory activity.     

Systemic cocaine challenge after chronic cocaine treatment reveals sensitization of extracellular dopamine levels in nucleus accumbens but direct cocaine perfusion into nucleus accumbens does not: implications for the neural locus of cocaine sensitization

Rats were treated chronically with 20 mg/kg/day cocaine (by intraperitoneal injection) for 16 days, followed by 7 days of cocaine wash-out. On the next day, rats were challenged with an acute dose of cocaine administered by one of two routes (systemic or intracranial), and extracellular dopamine (DA) in the nucleus accumbens (Acb) was measured by in vivo microdialysis. Rats acutely challenged systemically with 20 mg/kg cocaine showed enhanced Acb extracellular DA levels (compared to control rats that had not previously received chronic cocaine). However, rats acutely challenged with intracranial cocaine by perfusion of 10⁻⁵ M cocaine directly into the Acb did not. It is suggested that both the development and triggering of cocaine sensitization, as manifested by enhanced Acb DA content to subsequent acute cocaine challenge, may involve more than just neural mechanisms occurring locally within the Acb.     

Prevention of the Nigrostriatal Toxicity of 1-Methyl-4-Phenyl-1,2,3,6-Tetrahydropyridine by Inhibitors of 3,4-Dihydroxyphenylethylamine Transport

The 3,4-dihydroxyphenylethylamine (DA, dopamine) uptake inhibitors GBR 13,069, amfonelic acid, WIN-35,065-2, WIN-35,428, nomifensine, mazindol, cocaine, McN-5908, McN-5847, and McN-5292 were effective in preventing [3H]DA and [3H]1-methyl-4-phenylpyridinium (MPP+) uptake in rat and mouse neostriatal tissue slices. These DA uptake inhibitors also were effective in attenuating the MPP+-induced release of [3H]DA in vitro. 1-Methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP) administration to mice (6 X 25 mg/kg i.p.) resulted in a large (70-80%) decrement in neostriatal DA. WIN-35,428 (5 mg/kg), GBR 13,069 (10 mg/kg), McN-5292 (5 mg/kg), McN-5908 (2 mg/kg), and amfonelic acid (2 mg/kg), when administered intraperitoneally 30 min prior to each MPTP injection, fully protected against MPTP-induced neostriatal damage. Other DA uptake inhibitors showed partial protection in vivo at the doses selected. Desmethylimipramine did not prevent [3H]MPP+ uptake or MPP+-induced release of [3H]DA in vitro, and did not protect against MPTP neurotoxicity in vivo. These results support the hypothesis put forth previously by others that the active uptake of MPP+ by dopaminergic neurons is necessary for toxicity.     

Effects of cocaine on sodium dependent dopamine uptake in rat striatal synaptosomes

Initial velocity of uptake of dopamine (DA) has been measured in the presence of 1M cocaine as a function of both [DA] and [Na]. Although DA uptake is overwhelmingly dependent on sodium, it appears that a small amount of DA uptake takes place in the absence of sodium. This contrasts with a previous study of the sodium dependence of uptake without cocaine (referred to below as control), in which uptake was found to be 100% sodium dependent. The data were fitted to several rapid equilibrium models and the minimal best fit model identified. The interaction of transporter (C), DA (S), and Na⁺ (Na) in this present model is identical to the reaction scheme found previously to fit control data (no cocaine). Whereas the control model required translocation only as CNa₂S, in the presence of cocaine (I), two additional translocated species are required to fit the data (CS and CNaS). Another previous study of the interaction of carrier and cocaine at a constant [Na]₀ predicted that cocaine interacts with a transporter site other than the DA binding site and that uptake takes place as CS and CSI. The present results are consistent with the assumption that the CS and CNaS forms of the present model are actually CSI and CNaSI, since they are required to fit a model of the sodium dependence in the presence of cocaine, but are not required in the absence of cocaine.     

High Affinity Stereospecific Binding of [3H] Cocaine in Striatum and its Relationship to the Dopamine Transporter

A high affinity (K_D 35 nM) binding site for [³H]cocaine is detected in rat brain Striatum present at 2–3 pmol/mg protein of synaptic membranes. This binding is displaced by cocaine analogues with the same rank order as their inhibition of [³H]dopamine ([³H]DA) uptake into striatal synaptosomes (r = 0.99), paralleling the order of their central stimulant activity. The potent DA uptake inhibitors nomifensine, mazindol, and benztropine are more potent inhibitors of this high affinity [³H]cocaine binding than desipramine and imipramine. Cathinone and amphetamine, which are more potent central stimulants than cocaine, displace the high affinity [³H] cocaine binding stereos-pecifically, but with lower potency (IC₅₀ ～ 1μM) than does cocaine. It is suggested that the DA transporter in Striatum is the putative “cocaine receptor.

Binding of [³H] cocaine, measured in 10 mM Na₂HPO₄-0.32 M sucrose, pH 7.4 buffer, is inhibited by physiologic concentrations of Na⁺ and K⁺ and by biogenic amines. DA and Na⁺ reduce the affinity of the putative “cocaine receptor” for [³H]cocaine without changing the B_max, suggesting that inhibition may be competitive. However, TRIS reduces [³H]cocaine binding non-competitively while Na⁺ potentiates it in TRIS buffer. Binding of [³H]mazindol is inhibited competitively by cocaine. In phosphate-sucrose buffer, cocaine and mazindol are equally potent in inhibiting [³H]mazindol binding, but in TRIS-NaCl buffer cocaine has 10 times lower potency. It is suggested that the cocaine receptor in the striatum may be an allosteric protein with mazindol and cocaine binding to overlapping sites, while Na⁺ and DA are allosteric modulators, which stabilize a lower affinity state for cocaine.     

Amphetamine augments action potential-dependent dopaminergic signaling in the striatum in vivo

Amphetamine (AMPH) is thought to disrupt normal patterns of action potential-dependent dopaminergic signaling by depleting dopamine (DA) vesicular stores and promoting non-exocytotic DA efflux. Voltammetry in brain slices concurrently demonstrates these key drug effects, along with competitive inhibition of neuronal DA uptake. Here, we perform comparable kinetic and voltammetric analyses in vivo to determine whether AMPH acts qualitatively and quantitatively similar in the intact brain. Fast-scan cyclic voltammetry measured extracellular DA in dorsal and ventral striata of urethane-anesthetized rats. Electrically evoked recordings were analyzed to determine K(m) and V(max) for DA uptake and vesicular DA release, while background voltammetric current indexed basal DA concentration. AMPH (0.5, 3, and 10 mg/kg i.p.) robustly increased evoked DA responses in both striatal subregions. The predominant contributor to these elevated levels was competitive uptake inhibition, as exocytotic release was unchanged in the ventral striatum and only modestly decreased in the dorsal striatum. Increases in basal DA levels were not detected. These results are consistent with AMPH augmenting action potential-dependent dopaminergic signaling in vivo across a wide, behaviorally relevant dose range. Future work should be directed at possible causes for the distinct in vitro and in vivo pharmacology of AMPH.     

High doses of amphetamine augment, rather than disrupt, exocytotic dopamine release in the dorsal and ventral striatum of the anesthetized rat

High doses of amphetamine (AMPH) are thought to disrupt normal patterns of action potential-dependent dopaminergic neurotransmission by depleting vesicular stores of dopamine (DA) and inducing robust non-exocytotic DA release or efflux via dopamine transporter (DAT) reversal. However, these cardinal AMPH actions have been difficult to establish definitively in vivo. Here, we use fast-scan cyclic voltammetry (FSCV) in the urethane-anesthetized rat to evaluate the effects of 10 and 20 mg/kg AMPH on vesicular DA release and DAT function in dorsal and ventral striata. An equivalent high dose of cocaine (40 mg/kg) was also examined for comparison to psychostimulants acting preferentially by DAT inhibition. Parameters describing exocytotic DA release and neuronal DA uptake were determined from dynamic DA signals evoked by mild electrical stimulation previously established to be reinforcing. High-sensitivity FSCV with nanomolar detection was used to monitor changes in the background voltammetric signal as an index of DA efflux. Both doses of AMPH and cocaine markedly elevated evoked DA levels over the entire 2-h time course in the dorsal and ventral striatum. These increases were mediated by augmented vesicular DA release and diminished DA uptake typically acting concurrently. AMPH, but not cocaine, induced a slow, DA-like rise in some baseline recordings. However, this effect was highly variable in amplitude and duration, modest, and generally not present at all. These data thus describe a mechanistically similar activation of action potential-dependent dopaminergic neurotransmission by AMPH and cocaine in vivo. Moreover, DA efflux appears to be a unique, but secondary, AMPH action.