Abstract
Binding of Zn(2+) to an endogenous binding site in the dopamine transporter (DAT) leads to inhibition of dopamine (DA) uptake and enhancement of carrier-mediated substrate efflux. To elucidate the molecular mechanism for this dual effect, we expressed the DAT and selected mutants in Xenopus laevis oocytes and applied the two-electrode voltage clamp technique together with substrate flux studies employing radiolabeled tracers. Under voltage clamp conditions we found that Zn(2+) (10 mum) enhanced the current induced by both DA and amphetamine. This was not accompanied by a change in the uptake rate but by a marked increase in the charge/DA flux coupling ratio as assessed from concomitant measurements of [(3)H]DA uptake and currents in voltage-clamped oocytes. These data suggest that Zn(2+) facilitates an uncoupled ion conductance mediated by DAT. Whereas this required substrate in the wild type (WT), we observed that Zn(2+) by itself activated such a conductance in a previously described mutant (Y335A). This signifies that the conductance is not strictly dependent on an active transport process. Ion substitution experiments in Y335A, as well as in WT, indicated that the uncoupled conductance activated by Zn(2+) was mainly carried by Cl(-). Experiments in oocytes under non-voltage-clamped conditions revealed furthermore that Zn(2+) could enhance the depolarizing effect of substrates in oocytes expressing WT. The data suggest that by potentiating an uncoupled Cl(-) conductance, Zn(2+) is capable of modulating the membrane potential of cells expressing DAT and as a result cause simultaneous inhibition of uptake and enhancement of efflux.
Highlights
The dopamine transporter (DAT)1 belongs to the family of Naϩ/ClϪ-coupled transporters and plays a key role in termina
Under voltage clamp conditions we found that Zn2؉ (10 M) enhanced the current induced by both DA and amphetamine
Whereas cocaine binds to DAT and blocks transport activity [1,2,3,4], amphetamines are substrates that are actively transported by the DAT [5, 6]
Summary
The dopamine transporter (DAT) belongs to the family of Naϩ/ClϪ-coupled transporters and plays a key role in termina-. DAT is capable of Naϩ-dependent transmembrane uptake and of mediating dopamine efflux [7, 8] This can be observed under membrane depolarizing conditions or it can be elicited by extracellular substrates [7, 8]. The electrophysiological analyses have revealed several conducting states in the DAT These include, in addition to the substrate-transport coupled current, a substrate-dependent uncoupled conductance and a tonic leak that is blocked by cocaine [14]. In contrast to our expectations, we found that Zn2ϩ did not slow efflux but rather enhanced AMPHinduced efflux of the substrate MPPϩ (methyl-phenyl-pyridinium) both in transfected cells and in striatal slices [34] This identified Zn2ϩ as the first known modulator of DAT that differentially modulates inward and outward transport; none-. The data support a new principle for modulation of a Naϩ/ ClϪ-coupled transporter; Zn2ϩ is the first example of an allosteric modulator that can regulate transporter function by potentiating a specific uncoupled ion conductance
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