Binding of uptake blockers to the neuronal dopamine transporter: further investigation about cationic and anionic requirements.

Effects of ions on the binding of uptake blockers to the rat dopamine transporter (rDAT) labelled with [3H]WIN 35,428 [2beta-carbomethoxy-3beta-(4-fluorophenyl)-[3H] tropane] and [3H]mazindol were studied at 20 degrees C. [3H]WIN 35,428 binding increased with Na+ concentrations of up to 10-60 mM and decreased at higher concentrations. At pH 7.4, incubation media containing NaCl and/or Na2HPO4/NaH2PO4 were less stimulant than an NaHCO3/NaH2PO4 medium and they shifted maximal binding values to higher ionic concentrations. In an NaHCO3/NaH2PO4-buffered medium, Na+ concentrations >10 mM decreased the binding of 0.2 nM [3H]WIN 35,428, but an increase of the radioligand concentration shifted this decrease to the right. [3H]Mazindol binding was stimulated by Na+ concentrations < or =10 mM and was rather unaffected at higher concentrations. The inhibition of [3H]WIN 35,428 binding produced by 130 mM Na+ was independent of the nature of the anion; in contrast, isothionate and H2PO4-/HCO3 produced a more pronounced inhibition of the [3H]mazindol binding than Cl- and Br-, whereas I- tended to be a stimulant. Ca2+ and Mg2+ more potently inhibited the [3H]WIN 35,428 binding than K+. All these cations recognize a site which is not mutually exclusive with that of the radioligand since they induced the dissociation of the [3H]WIN 35,428-rDAT complex, an effect which was reduced (K+) or modified (Ca2+) when the Na+ concentration was increased. This site is likely to be the Na+ site by which low Na+ concentrations allosterically stimulate the uptake blocker binding. However, the intensity of the cation-induced dissociations was moderate and the main component of the binding inhibition that these cations produced results from the occupancy of a cation site, mutually exclusive with that of the radioligand. Thus, the WIN 35,428 binding inhibition produced by Ca2+, K+ and Na+ was competitive, and Na+ reduced the inhibitory potency of Ca2+ and K+. This reduction was more intense for Ca2+ and Mg2+ than for K+, suggesting that occupancy of the cation site by a divalent cation activated a strong negative allosteric interaction between this site and the Na+ site. Decrease in the Na+ concentration from 10 mM to 5 mM, or replacement of 5 mM HCO3-/H2PO4- by an equimolar concentration of isethionate or Cl- did not modify [3H]WIN 35,428 binding dissociation. Level(s) at which anions stimulate and inhibit the binding of uptake blockers remain uncertain and could be specific for each radioligand.

Although chemically related to amineptine, the antidepressant tianeptine is not a dopamine uptake inhibitor.

We investigated whether the antidepressant tianeptine shares the dopamine uptake inhibitory properties of the chemically related antidepressant amineptine. Tianeptine dose dependently (5, 10, 20, 40 mg/kg IP) increased locomotor activity in mice. This stimulant effect (20 mg/kg IP) was dose dependently prevented not only by the D1 dopamine receptor antagonist SCH 23390 (7.5. 15, 30 microg/kg SC), but also by the D2 dopamine receptor antagonist haloperidol (50, 100, 200 microg/kg IP), in contrast to that elicited by dopamine uptake inhibitors. Where the latter prevent dexamphetamine-induced (3 mg/kg SC) reversion of akinesia in mice pretreated with reserpine (4 mg/kg SC, 5 h before test), tianeptine (20 mg/kg IP, 30 min before test) did not. Tested up to a concentration of 10-4 M, tianeptine did neither inhibit the [3H]dopamine uptake into mouse striatal synaptosomes nor compete in vitro with the specific binding of [3H]WIN 35,428 at dopamine transporters from striatal membranes. Finally, in mice injected IV with a tracer dose of [3H]WIN 35,428 (1 microCi), the highest tested dose of tianeptine (40 mg/kg IP) did not reduce the specific binding of the radioligand to striatal dopamine transporters. It is concluded that the antidepressant effect of tianeptine does not depend upon a blockade of the neuronal dopamine transporter.

Effect of low concentrations of K+ and Cl- on the Na(+)-dependent neuronal uptake of [3H] dopamine.

The specific uptake of [3H] dopamine (DA) was studied using a crude synaptosomal fraction obtained from rat striatum. In a medium containing a 10 mM NaHCO3/NaH2PO4 buffer and no added K+ ions, addition of NaCl elicited an increase in DA uptake for Na+ concentrations from 10 to 60 mM, and then a decrease of uptake for Na+ concentrations up to 130 mM. These data confirm that rather low NaCl concentrations produce a maximal DA uptake. This biphasic curve of uptake resulted from significant changes in the Vmax of the DA uptake. Except for 10 mM Na+, this curve was not significantly modified when 9 mM NaHCO3/NaH2PO4 were replaced by 9 mM NaCl. This result indicates that the Cl- dependence of the DA uptake is mainly secondary to the Na+ dependence. Addition of KCl up to 3 mM did not modify the ascending part of the NaCl-dependent uptake curve. In contrast, the reduction in uptake produced by high Na+ concentrations was prevented in a concentration-dependent manner by KCl; this effect resulted from a decrease in the Km and an increase in the Vmax for the uptake. Measurements of membrane potential, with the help of the fluorescent probe 3, 3'-diethylthiadicarbocyanine iodide [DiSC2(5)] and purified synaptosomes prepared from rat striatum and cerebral cortex, revealed that addition of 3 mM KCl to a medium containing a high Na+ concentration and no K+ ions produced a marked and stable decrease in the fluorescence level. This decrease which corresponds to an increase in membrane polarization was blocked by 0.1 mM ouabain. These data suggest that low K+ concentrations are likely to prevent the decrease in uptake elicited by high Na+ concentrations by restoration, via a Na+/K+ ATPase-mediated mechanism, of the membrane potential and/or a transmembrane electrochemical Na+ gradient more favourable to DA uptake.