Roxanne A. Vaughan

Protein Kinase C-mediated Phosphorylation and Functional Regulation of Dopamine Transporters in Striatal Synaptosomes

Dopamine transporters (DATs) are members of a family of Na+- and Cl−-dependent neurotransmitter transporters responsible for the rapid clearance of dopamine from synaptic clefts. The predicted primary sequence of DAT contains numerous consensus phosphorylation sites. In this report we demonstrate that DATs undergo endogenous phosphorylation in striatal synaptosomes that is regulated by activators of protein kinase C. Rat striatal synaptosomes were metabolically labeled with [32P]orthophosphate, and solubilized homogenates were subjected to immunoprecipitation with an antiserum specific for DAT. Basal phosphorylation occurred in the absence of exogenous treatments, and the phosphorylation level was rapidly increased when synaptosomes were treated with the phosphatase inhibitors okadaic acid or calyculin. Treatment of synaptosomes with the protein kinase C activator phorbol 12-myristate 13-acetate (PMA) also increased the level of phosphate incorporation. This occurred within 10 min and was dosedependent between 0.1 and 1 μm PMA. DAT phosphorylation was also significantly increased by two other protein kinase C activators, (−)-indolactam V and 1-oleoyl-2-acetyl-sn-glycerol. The inactive phorbol ester 4α-phorbol 12,13-didecanoate at 10 μm was without effect, and PMA-induced phosphorylation was blocked by treatment of synaptosomes with the protein kinase C inhibitors staurosporine and bisindoylmaleimide. These results indicate that DATs undergo rapidin vivo phosphorylation in response to protein kinase C activation and that a robust mechanism exists in synaptosomes for DAT dephosphorylation. Dopamine transport activity in synaptosomes was reduced by all treatments that promoted DAT phosphorylation, with comparable dose, time, and inhibitor characteristics. The change in transport activity was produced by a reduction inV max with no significant effect on theK m for dopamine. These results suggest that synaptosomal dopamine transport activity is regulated by phosphorylation of DAT and present a potential mechanism for local neuronal control of synaptic neurotransmitter levels and consequent downstream neural activity.

Phorbol Esters Increase Dopamine Transporter Phosphorylation and Decrease Transport Vmax

Abstract: Sodium‐ and chloride‐coupled transport of dopamine from synapses into presynaptic terminals plays a key role in terminating dopaminergic neurotransmission. Regulation of the function of the dopamine transporter, the molecule responsible for this translocation, is thus of interest. The primary sequence of the dopamine transporter contains multiple potential phosphorylation sites, suggesting that the function of the transporter could be regulated by phosphorylation. Previous work from this laboratory has documented that phorbol ester activation of protein kinase C (PKC) decreases dopamine transport Vmax in transiently expressing COS cells. In the present report, we document in vivo phosphorylation of the rat dopamine transporter stably expressed in LLC‐PK1 cells and show that phosphorylation is increased threefold by phorbol esters. Dopamine uptake is also regulated by phorbol esters in these cells; phorbol 12‐myristate 13‐acetate (PMA) reduces transport Vmax by 35%. Parallels between the time course, concentration dependency, and staurosporine sensitivity of alterations in transporter phosphorylation and transporter Vmax suggest that dopamine transporter phosphorylation involving PKC could contribute to this decreased transporter function. Phosphorylation of the dopamine transporter by PKC or by a PKC‐activated kinase could be involved in rapid neuroadaptive processes in dopaminergic neurons.

Tyr-95 and Ile-172 in Transmembrane Segments 1 and 3 of Human Serotonin Transporters Interact to Establish High Affinity Recognition of Antidepressants

In previous studies examining the structural determinants of antidepressant and substrate recognition by serotonin transporters (SERTs), we identified Tyr-95 in transmembrane segment 1 (TM1) of human SERT as a major determinant of binding for several antagonists, including racemic citalopram ((RS)-CIT). Here we described a separate site in hSERT TM3 (Ile-172) that impacts (RS)-CIT recognition when switched to the corresponding Drosophila SERT residue (I172M). The hSERT I172M mutant displays a marked loss of inhibitor potency for multiple inhibitors such as (RS)-CIT, clomipramine, RTI-55, fluoxetine, cocaine, nisoxetine, mazindol, and nomifensine, whereas recognition of substrates, including serotonin and 3,4-methylenedioxymethamphetamine, is unaffected. Selectivity for antagonist interactions is evident with this substitution because the potencies of the antidepressants tianeptine and paroxetine are unchanged. Reduced cocaine analog recognition was verified in photoaffinity labeling studies using [125I]MFZ 2-24. In contrast to the I172M substitution, other substitutions at this position significantly affected substrate recognition and/or transport activity. Additionally, the mouse mutation (mSERT I172M) exhibits similar selective changes in inhibitor potency. Unlike hSERT or mSERT, analogous substitutions in mouse dopamine transporter (V152M) or human norepinephrine transporter (V148M) result in transporters that bind substrate but are deficient in the subsequent translocation of the substrate. A double mutant hSERT Y95F/I172M had a synergistic impact on (RS)-CIT recognition (∼10,000-fold decrease in (RS)-CIT potency) in the context of normal serotonin recognition. The less active enantiomer (R)-CIT responded to the I172M substitution like (S)-CIT but was relatively insensitive to the Y95F substitution and did not display a synergistic loss at Y95F/I172M. An hSERT mutant with single cysteine substitutions in TM1 and TM3 resulted in formation of a high affinity cadmium metal coordination site, suggesting proximity of these domains in the tertiary structure of SERT. These studies provided evidence for distinct binding sites coordinating SERT antagonists and revealed a close interaction between TM1 and TM3 differentially targeted by stereoisomers of CIT.

Cholinergic axon terminals in the ventral tegmental area target a subpopulation of neurons expressing low levels of the dopamine transporter.

Cholinergic activation of dopaminergic neurons in the ventral tegmental area (VTA) is thought to play a major role in cognitive functions and reward. These dopaminergic neurons differentially project to cortical and limbic forebrain regions, where their terminals differ in levels of expression of the plasmalemmal dopamine transporter (DAT). This transporter selectively identifies dopaminergic neurons, whereas the vesicular acetylcholine transporter (VAchT) is present only in the neurons that store and release acetylcholine. We examined immunogold labeling for DAT and immunoperoxidase localization of VAchT antipeptide antisera in single sections of the rat VTA to determine whether dopaminergic somata and dendrites in this region differ in their levels of expression of DAT and/or input from cholinergic terminals. VAchT immunoreactivity was prominently localized to membranes of small synaptic vesicles in unmyelinated axons and axon terminals. VAchT‐immunoreactive terminals formed almost exclusively asymmetric synapses with dendrites. Of 159 dendrites that were identified as cholinergic targets, 35% contained plasmalemmal DAT, and 65% were without detectable DAT immunoreactivity. The DAT‐immunoreactive dendrites postsynaptic to VAchT‐labeled terminals contained less than half the density of gold particles as seen in other dendrites receiving input only from unlabeled terminals. These results suggest selective targeting of cholinergic afferents in the VTA to non‐dopaminergic neurons and a subpopulation of dopaminergic neurons that have a limited capacity for plasmalemmal reuptake of dopamine, a characteristic of those that project to the frontal cortex. J. Comp. Neurol. 410:197–210, 1999.

Mechanisms of dopamine transporter regulation in normal and disease states

The dopamine (DA) transporter (DAT) controls the spatial and temporal dynamics of DA neurotransmission by driving reuptake of extracellular transmitter into presynaptic neurons. Many diseases such as depression, bipolar disorder, Parkinsons disease (PD), and attention deficit hyperactivity disorder (ADHD) are associated with abnormal DA levels, implicating DAT as a factor in their etiology. Medications used to treat these disorders and many addictive drugs target DAT and enhance dopaminergic signaling by suppressing transmitter reuptake. We now understand that the transport and binding properties of DAT are regulated by complex and overlapping mechanisms that provide neurons with the ability to modulate DA clearance in response to physiological demands. These processes are controlled by endogenous signaling pathways and affected by exogenous transporter ligands, demonstrating their importance for normal neurotransmission, drug abuse, and disease treatments. Increasing evidence supports the disruption of these mechanisms in DA disorders, implicating dysregulation of transport in disease etiologies and suggesting these processes as potential points for therapeutic manipulation of DA availability.

Flotillin-1 is essential for PKC-triggered endocytosis and membrane microdomain localization of DAT

Plasmalemmal neurotransmitter transporters (NTTs) regulate the level of neurotransmitters, such as dopamine (DA) and glutamate, after their release at brain synapses. Stimuli including protein kinase C (PKC) activation can lead to the internalization of some NTTs and a reduction in neurotransmitter clearance capacity. We found that the protein Flotillin-1 (Flot1), also known as Reggie-2, was required for PKC-regulated internalization of members of two different NTT families, the DA transporter (DAT) and the glial glutamate transporter EAAT2, and we identified a conserved serine residue in Flot1 that is essential for transporter internalization. Further analysis revealed that Flot1 was also required to localize DAT within plasma membrane microdomains in stable cell lines, and was essential for amphetamine-induced reverse transport of DA in neurons but not for DA uptake. In sum, our findings provide evidence for a critical role of Flot1-enriched membrane microdomains in PKC-triggered DAT endocytosis and the actions of amphetamine.

Psychoactive Substrates Stimulate Dopamine Transporter Phosphorylation and Down-regulation by Cocaine-sensitive and Protein Kinase C-dependent Mechanisms

Dopamine transporters (DATs) undergo intracellular sequestration and functional down-regulation upon exposure to psychostimulant substrates. To investigate the potential mechanism underlying these responses, we examined the acute in vitro and in vivo effects of amphetamine and methamphetamine (METH) on phosphorylation and down-regulation of rat DAT using wild type and N-terminal truncation mutants. Phosphorylation of DAT assessed by 32PO4 metabolic labeling was increased up to 2-fold by in vitro treatment of rDAT LLC-PK1 cells with amphetamine or METH and was similarly increased in rat striatal tissue by in vitro application or in vivo injection of METH. The dopamine transport blocker (-)-cocaine did not affect DAT phosphorylation but prevented the phosphorylation increase induced by METH. Phosphorylation of DAT induced by METH was also prevented by the protein kinase C blocker bisindoylmaleimide I and was absent in an N-terminally truncated protein that lacks the first 21 residues including 6 serines that also represent the site of phorbol ester induced phosphorylation. Down-regulation of transport induced by METH was also cocaine- and protein kinase C-dependent but was retained in the N-terminal truncation mutant. These results demonstrate that transport or binding of METH stimulates DAT phosphorylation and down-regulation by a mechanism that requires protein kinase C but that METH-induced down-regulation can occur independently of direct transporter phosphorylation. The finding that DAT phosphorylation is stimulated by amphetamines reveals a previously unknown effect of these drugs that is not produced by cocaine and may be related to reinforcement.

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. 2β‐carbomethoxy‐3β‐(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 [3H]DA uptake, but caused undetectable [3H]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 [125I]‐3β‐(p‐chlorophenyl)tropane‐2β‐carboxylic acid ([125I]RTI‐82). Unexpectedly, in this mutant, cocaine‐like drugs remained potent inhibitors of [3H]DA uptake. CFT solely raised the Km of [3H]DA uptake in wild‐type hDAT, but increased Km and decreased Vmax 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.

Phorbol ester induced trafficking-independent regulation and enhanced phosphorylation of the dopamine transporter associated with membrane rafts and cholesterol.

We examined the mechanisms involved in protein kinase C (PKC)‐dependent down‐regulation of dopamine transporter (DAT) activity and cell surface expression by treating heterologously expressing cells with the clathrin‐mediated endocytosis inhibitor concanavalin A (Con A) or the cholesterol depleter/membrane raft disrupter methyl‐β‐cyclodextrin (MβC) prior to treatment with the PKC activator phorbol 12‐myristate, 13‐acetate (PMA). Con A blocked PMA‐induced surface reductions of DAT but only partially inhibited down‐regulation, while MβC partially blocked down‐regulation but did not inhibit loss of cell surface DAT, demonstrating that PKC‐induced DAT down‐regulation occurs by a combination of trafficking and non‐trafficking processes. Using density‐gradient centrifugation, we found that DATs are distributed approximately equally between Triton‐insoluble, cholesterol‐rich membrane rafts and Triton‐soluble non‐raft membranes. DATs in both populations are present at the cell surface and are active for dopamine and cocaine binding. PMA‐induced loss of cell surface DAT occurred only from non‐raft populations, demonstrating that non‐raft DATs are regulated by trafficking events and indicating the likelihood that the cholesterol‐dependent non‐trafficking regulatory mechanism occurs in rafts. PMA did not affect the DAT raft‐non‐raft distribution but stimulated the phosphorylation of DAT to a substantially greater level in rafts than non‐rafts. These findings reveal a previously unknown role for cholesterol in DAT function and demonstrate the presence of distinct subcellular DAT populations that possess multiple regulatory differences that may impact dopaminergic neurotransmission.

Nature of methamphetamine-induced rapid and reversible changes in dopamine transporters

The nature of methamphetamine-induced rapid and transient decreases in dopamine transporter activity was investigated. Regional specificity was demonstrated, since [3H]dopamine uptake was decreased in synaptosomes prepared from the striatum, but not nucleus accumbens, of methamphetamine-treated rats. Differences among effects on dopamine transporter activity and ligand binding were also observed, since a single methamphetamine administration decreased [3H]dopamine uptake without altering [3H]WIN35428 ([3H](-)-2-beta-carbomethoxy-3-beta-(4-fluorophenyl)tropane 1,5-naphthalenedisulfonate) binding in synaptosomes prepared 1 h after injection. Moreover, multiple methamphetamine injections caused a greater decrease in [3H]dopamine uptake than [3H]WIN35428 binding in synaptosomes prepared I h after dosing. Finally, decreases in [3H]dopamine uptake, but not [3H]WIN35428 binding, were partially reversed 24 h after multiple methamphetamine injections. Western blotting indicated that saline- and methamphetamine-affected dopamine transporters co-migrated on sodium dodecyl sulfate (SDS) gels at approximately 80 kDa, and that acute, methamphetamine-induced decreases in [3H]dopamine uptake were not due to loss of dopamine transporter protein. These findings demonstrate heretofore-uncharacterized features of the acute effect of methamphetamine on dopamine transporters.