Clearance of synaptically released dopamine is regulated by the plasmalemmal dopamine transporter (DAT), an integral membrane protein that resides within a complex lipid milieu. Here we demonstrate that cholesterol, a major component of the lipid bilayer, can modulate the conformation of DAT and alter cocaine binding to DAT. In striatal synaptosomes and transfected cells, DAT was in cholesterol-rich membrane fractions after mild detergent extraction. After increasing the membrane cholesterol content by treatment of water-soluble cholesterol (cholesterol mixed with methyl--cyclodextrin), we observed an increase in DAT binding B max values for cocaine analogs [3 H]WIN35428 and [ 125 I]RTI-55, but similar levels of DAT proteins on the cell surface were shown by surface biotinylation assays. Membrane cholesterol addition also markedly enhanced the accessibility of cysteine sulfhydryl moieties in DAT as probed by a membrane-impermeable maleimide-biotin conjugate. We identified cysteine 306, a juxtamembrane residue on transmembrane domain 6 (TM6) of DAT, as the intrinsic residue exhibiting enhanced reactivity. Similar effects on DAT cysteine accessibility and radioligand binding were observed with addition of zinc, a reagent known to promote the outward facing conformation of DAT. Using substituted cysteine mutants on various positions likely to be extracellular, we identified additional residues located on TM1, TM6, TM7, and TM12 of DAT that are sensitive to alterations in the membrane cholesterol content. Our findings in transfected cells and native tissues support the hypothesis that DAT adopts an outward facing conformation in a cholesterol-rich membrane environment, suggesting a novel modulatory role of the surrounding membrane lipid milieu on DAT function. The dopamine transporter (DAT)2 has a primary function to reaccumulate dopamine (DA) molecules into the presynaptic nerve terminal, thus limiting the extent and duration of DA signaling. Cocaine, a natural alkaloid from the leaves of the coca plant, is among the most widely abused drugs in modern society. Cocaine binds to DAT with high affinity and inhibits the transport of DA, resulting in prolonged DA neurotransmission in the brain. The enhanced DA signaling in the mesolimbic system is believed to be the main mechanism of action for cocaine addiction (1-3).The DAT is a multispan integral membrane protein embedded in the plasmalemmal lipid bilayer, which comprises three main components: phospholipids, sphingolipids, and cholesterol. Cholesterol-rich domains within the membrane have been proposed to serve as a dynamic platform for membrane protein compartmentalization and organization (4, 5). Early reports have shown that the sodium-dependent uptake of ␥-aminobutyric acid (GABA) by brain synaptosomes or reconstituted proteoliposomes requires membrane cholesterol (6, 7). Recent studies on the serotonin transporter, norepinephrine transporter, glycine transporter, and excitatory amino acid transporters (EAATs) have demonstrated that they can be associated with ...
Background Treatment of Stimulant-Use Disorders remains a formidable challenge, and the dopamine transporter (DAT) remains a potential target for antagonist or agonist-like substitution therapies. Methods This review focuses on DAT ligands, such as benztropine, GBR 12909, modafinil, and DAT substrates derived from phenethylamine or cathinone that have atypical DAT-inhibitor effects, either in vitro or in vivo. The compounds are described from a molecular mechanistic, behavioral, and medicinal-chemical perspective. Results Possible mechanisms for atypicality at the molecular level can be deduced from the conformational cycle for substrate translocation. For each conformation, a crystal structure of a bacterial homolog is available, with a possible role of cholesterol, which is also present in the crystal of drosophila DAT. Although there is a direct relationship between behavioral potencies of most DAT inhibitors and their DAT affinities, a number of compounds bind to the DAT and inhibit dopamine uptake but do not share cocaine-like effects. Such atypical behavior, depending on the compound, may be related to slow DAT association, combined sigma-receptor actions, or bias for cytosol-facing DAT. Some structures are sterically small enough to serve as DAT substrates but large enough to also inhibit transport. Such compounds may display partial DA releasing effects, and may be combined with release or uptake inhibition at other monoamine transporters. Conclusions Mechanisms of atypical DAT inhibitors may serve as targets for the development of treatments for stimulant abuse. These mechanisms are novel and their further exploration may produce compounds with unique therapeutic potential as treatments for stimulant abuse.
Physical and Functional Interaction between the Dopamine Transporter and the Synaptic Vesicle Protein Synaptogyrin-3
Uptake through the dopamine transporter (DAT) represents the primary mechanism used to terminate dopaminergic transmission in brain. Although it is well known that dopamine (DA) taken up by the transporter is used to replenish synaptic vesicle stores for subsequent release, the molecular details of this mechanism are not completely understood. Here, we identified the synaptic vesicle protein synaptogyrin-3 as a DAT interacting protein using the split ubiquitin system. This interaction was confirmed through coimmunoprecipitation experiments using heterologous cell lines and mouse brain. DAT and synaptogyrin-3 colocalized at presynaptic terminals from mouse striatum. Using fluorescence resonance energy transfer microscopy, we show that both proteins interact in live neurons. Pulldown assays with GST (glutathione S-transferase) proteins revealed that the cytoplasmic N termini of both DAT and synaptogyrin-3 are sufficient for this interaction. Furthermore, the N terminus of DAT is capable of binding purified synaptic vesicles from brain tissue. Functional assays revealed that synaptogyrin-3 expression correlated with DAT activity in PC12 and MN9D cells, but not in the nonneuronal HEK-293 cells. These changes were not attributed to changes in transporter cell surface levels or to direct effect of the proteinprotein interaction. Instead, the synaptogyrin-3 effect on DAT activity was abolished in the presence of the vesicular monoamine transporter-2 (VMAT2) inhibitor reserpine, suggesting a dependence on the vesicular DA storage system. Finally, we provide evidence for a biochemical complex involving DAT, synaptogyrin-3, and VMAT2. Collectively, our data identify a novel interaction between DAT and synaptogyrin-3 and suggest a physical and functional link between DAT and the vesicular DA system.
The dopamine transporter (DAT) regulates dopamine (DA) neurotransmission by recapturing DA into the presynaptic terminals and is a principal target of the psychostimulant cocaine. The sigma-1 receptor (σR) is a molecular chaperone, and its ligands have been shown to modulate DA neuronal signaling, although their effects on DAT activity are unclear. Here, we report that the prototypical σR agonist (+)-pentazocine potentiated the dose response of cocaine self-administration in rats, consistent with the effects of the σR agonists PRE-084 and DTG (1,3-di--tolylguanidine) reported previously. These behavioral effects appeared to be correlated with functional changes of DAT. Preincubation with (+)-pentazocine or PRE-084 increased the B values of [H]WIN35428 binding to DAT in rat striatal synaptosomes and transfected cells. A specific interaction between σR and DAT was detected by co-immunoprecipitation and bioluminescence resonance energy transfer assays. Mutational analyses indicated that the transmembrane domain of σR likely mediated this interaction. Furthermore, cysteine accessibility assays showed that σR agonist preincubation potentiated cocaine-induced changes in DAT conformation, which were blocked by the specific σR antagonist CM304. Moreover, σR ligands had distinct effects on σR multimerization. CM304 increased the proportion of multimeric σRs, whereas (+)-pentazocine increased monomeric σRs. Together these results support the hypothesis that σR agonists promote dissociation of σR multimers into monomers, which then interact with DAT to stabilize an outward-facing DAT conformation and enhance cocaine binding. We propose that this novel molecular mechanism underlies the behavioral potentiation of cocaine self-administration by σR agonists in animal models.
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