Antibodies specific for the dopamine transporter (DAT) was developed and characterized by immunoblot analysis, immunoprecipitation, and immunocytochemistry, and used for immunolocalization of transporter protein in rat brain at the light microscopic level. Antibodies targeting the N-terminus, the second extracellular loop, and the C- terminus were generated from fusion proteins containing amino acid sequences from these respective regions. Immunoblot analysis demonstrated that N-terminus and loop antibodies were specific for expressed cloned DAT, recognized transporter protein in rat and human striatal membranes, and were sensitive to preabsorption with excess homologous fusion protein. Immunoprecipitation studies demonstrated that anti-DAT antisera recognized solubilized, radiolabeled DAT protein in a concentration-dependent manner. DAT immunocytochemistry with these antibodies were also sensitive to preabsorption with fusion protein and to lesions of dopaminergic mesostriatal and mesocorticolimbic pathways. Regional distribution of DAT coincided with established dopaminergic innervation of several regions, including ventral mesencephalon, medial forebrain bundle, and dorsal and ventral striatum. However, certain mismatches between immunocytochemical distributions of DAT and tyrosine hydroxylase were apparent, indicating that dopaminergic systems are heterogeneous and may use independent mechanisms for the regulation of dopamine levels in brain. The generation of specific DAT antibodies will permit further characterization of the cellular and subcellular localization of DAT protein, and of dopaminergic circuits in neurological and psychiatric disorders.
Mutations in alpha-synuclein, a protein highly enriched in presynaptic terminals, have been implicated in the expression of familial forms of Parkinson's disease (PD) whereas native alpha-synuclein is a major component of intraneuronal inclusion bodies characteristic of PD and other neurodegenerative disorders. Although overexpression of human alpha-synuclein induces dopaminergic nerve terminal degeneration, the molecular mechanism by which alpha-synuclein contributes to the degeneration of these pathways remains enigmatic. We report here that alpha-synuclein complexes with the presynaptic human dopamine transporter (hDAT) in both neurons and cotransfected cells through the direct binding of the non-A beta amyloid component of alpha-synuclein to the carboxyl-terminal tail of the hDAT. alpha-Synuclein--hDAT complex formation facilitates the membrane clustering of the DAT, thereby accelerating cellular dopamine uptake and dopamine-induced cellular apoptosis. Since the selective vulnerability of dopaminergic neurons in PD has been ascribed in part to oxidative stress as a result of the cellular overaccumulation of dopamine or dopamine-like molecules by the presynaptic DAT, these data provide mechanistic insight into the mode by which the activity of these two proteins may give rise to this process.
GABA(A) (gamma-aminobutyric-acid A) and dopamine D1 and D5 receptors represent two structurally and functionally divergent families of neurotransmitter receptors. The former comprises a class of multi-subunit ligand-gated channels mediating fast interneuronal synaptic transmission, whereas the latter belongs to the seven-transmembrane-domain single-polypeptide receptor superfamily that exerts its biological effects, including the modulation of GABA(A) receptor function, through the activation of second-messenger signalling cascades by G proteins. Here we show that GABA(A)-ligand-gated channels complex selectively with D5 receptors through the direct binding of the D5 carboxy-terminal domain with the second intracellular loop of the GABA(A) gamma2(short) receptor subunit. This physical association enables mutually inhibitory functional interactions between these receptor systems. The data highlight a previously unknown signal transduction mechanism whereby subtype-selective G-protein-coupled receptors dynamically regulate synaptic strength independently of classically defined second-messenger systems, and provide a heuristic framework in which to view these receptor systems in the maintenance of psychomotor disease states.
Cloning, expression, and localization of a chloride-facilitated, cocaine-sensitive serotonin transporter from Drosophila melanogaster.
We report here on the isolation and characterization of a serotonin (SHT) transporter from Drosophila melanogaster. A 3.1-kb complementary DNA clone (dSERT) was found to encode a protein of 622 amino acid residues with a predicted molecular mass of w69 kDa and a putative transmembrane topology characteristic of cloned members of the mammalian Na+/Cl-neurotransmitter cotransporter gene family. dSERT displays highest overall amino acid sequence identity with the mammalian 5HT (51%), norepinephrine (47%), and dopamine (47%) transporters and shares with all transporters 104 absolutely conserved amino acid residues.Upon tnsient expression in HeLa cells, dSERT exhibited saturabl, high-affinity, and sodium-dependent [3H5HT uptake with esimated K and V. values of w500 nM and 5.2 x 1o-i8 mol per cell per min, respectively. In marked contrast to the human SERT (hSERT), SHT-mediated transport by dSERT was not absolutely dependent on extracellular Cl-, while the sodium-dependent uptake of MHT was facilitatd by Increased extracellular Cl-concentrations. dSERT disys a pharmacological profile and rank order of potency consistent with, but not identical to, mammalian 5HT transporters. Comparison of the afnities of various compounds for the inhibiion of 5HT transport by both dSERT and hSERT revealed that antidepressants were 3-to 300-fold less potent on dSERT than on hSERT, while mazindol displayed w30-fold greater potency for dSERT. Both cocaine and RTI-55 inhibited 5HT uptake by dSERT with estmated inhibition constants of 500 nM, while high concentrations (>10 FM) of dopmin, norepinephrine, octopamine, tramine, and histamine failed to inhibit transport. In situ hybridization reveals the selective expression of dSERT mRNA to specific cell bodies in the ventral gagulon of the embryonic and larval Drosophila nervous system with a distribution pattern virtually identical to that of 5HT-containing neurons. The dSERT gene was mapped to position 60C on chromosome 2. The availability of the gene e ing the unique ion dependence and pharmacological characteristics of dSERT may allow for identification of those amino acid residues and structural motifs that confer the phannacologrc specificity and genetic regulation of the 5HT transport process. Serotonin (5HT) plays a vital role in modulation ofa variety of biochemical and physiological functions in the central nervous system, including sleep, appetite, and pain perception, and has been shown to regulate complex behavioral phenomena, such as learning and memory in invertebrates (1, 2). Numerous studies have provided evidence for production of SHT in Drosophila as well as its cell-specific localization in neurons within the central nervous system (3). Released from neuronal terminals into the synaptic cleft, 5HT is believed to mediate its effects in Drosophila via an interaction with specific multiple cell surface 5HT receptors (4, 5), which in turn are coupled to subtype-specific guanine nucleotide-binding proteins (see ref.6 and references therein) activating various membran...
Modification of the transport velocity of both the native neuronal and cloned presynaptic dopamine transporter (DAT) has been reported following activation/inhibition of second messenger system pathways. In order to identify the mechanism by which the functional activity of human DAT (hDAT) is regulated, we assessed the [3H]dopamine uptake kinetics, [3H] CFT binding characteristics, and, via immunofluorescent confocal microscopy, the cellular localization profiles of the hDAT expressed in both Sf9 and COS-7 cells following modulation of protein kinase C (PKC)- and protein kinase A (PKA)-dependent pathways. As with both native neuronal and cloned DATs, acute exposure of hDAT expressing Sf9 cells to the PKC activator PMA (1 microM), but not alphaPDD, reduced the Vmax (approximately 1 pmol/min/10(5) cells) for [3H]DA uptake by approximately 40%, an effect which was blocked by the protein kinase inhibitor staurosporine. Pretreatment of cells with staurosporine (500 nM) alone, however, increased [3H]DA uptake velocity by approximately 30%, an effect mimicked by the potent PKA inhibitor Rp-cAMPS. Activation of PKA-dependent pathways with Sp-cAMPS did not significantly modify DA uptake. Neither the Km of [3H]DA uptake (approximately 200 nM) nor the affinity of various substrates and transport inhibitors was altered by either PMA or staurosporine treatment. Despite changes in functional dopamine uptake velocity by PKC/PKA-dependent mechanisms, the estimated density of hDAT as indexed by whole-cell [3H] CFT binding was unchanged. Immunofluorescent confocal microscopy demonstrated that the observed functional consequence of PKC activation on [3H]DA uptake is associated with the rapid sequestration/internalization of hDAT protein from the cell surface, while the increase in DA uptake following PKC/PKA inhibition is the result of the recruitment of internalized or intracellular transporters to the plasma membrane. Identical rapid translocation patterns were observed in similarly treated COS-7 cells transiently expressing hDAT. These data suggest that the differential regulation of DAT transport capacity by both PKC- and PKA-dependent pathways are not a result of modifications in DAT catalytic activity. Moreover, the rapid shuttling of DATs between the plasma membrane and intracellular compartments provides an efficient means by which native DAT function may be regulated by second messenger systems, possibly following activation of presynaptic dopaminergic receptors, and suggests a role for cytoskeletal components in the dynamic regulation of DAT function.
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