Palmitoylation controls dopamine transporter kinetics, degradation, and protein kinase C-dependent regulation

Palmitoylation is a lipid modification that confers diverse functions to target proteins and is a contributing factor for many neuronal diseases. In this study, we demonstrate using [(3)H]palmitic acid labeling and acyl-biotinyl exchange that native and expressed dopamine transporters (DATs) are palmitoylated, and using the palmitoyl acyltransferase inhibitor 2-bromopalmitate (2BP), we identify several associated functions. Treatment of rat striatal synaptosomes with 2BP using lower doses or shorter times caused robust inhibition of transport V(max) that occurred with no losses of DAT protein or changes in DAT surface levels, indicating that acute loss of palmitoylation leads to reduction of transport kinetics. Treatment of synaptosomes or cells with 2BP using higher doses or longer times resulted in DAT protein losses and production of transporter fragments, implicating palmitoylation in regulation of transporter degradation. Site-directed mutagenesis indicated that palmitoylation of rat DAT occurs at Cys-580 at the intracellular end of transmembrane domain 12 and at one or more additional unidentified site(s). Cys-580 mutation also led to production of transporter degradation fragments and to increased phorbol ester-induced down-regulation, further supporting palmitoylation in opposing DAT turnover and in opposing protein kinase C-mediated regulation. These results identify S-palmitoylation as a major regulator of DAT properties that could significantly impact acute and long term dopamine transport capacity.     

Apomorphine Does Not Alter Amphetamine-Induced Dopamine Release Measured in Striatal Dialysates

Amphetamine facilitates the release of dopamine from nerve terminals, but the mechanisms underlying this effect have not been fully delineated. The present experiments were designed to test the extent to which amphetamine-induced dopamine release is dependent on impulse flow and autoreceptor function in dopaminergic neurons. Rats were pretreated with a low dose of apomorphine (0.05 mg/kg) to inhibit dopamine neuronal activity, and the striatal dopaminergic response to amphetamine (0.5 mg/kg) was assessed by in vivo dialysis in freely moving animals. Consistent with previous results, apomorphine alone substantially decreased, whereas amphetamine increased, striatal dialysate dopamine concentrations. However, whereas apomorphine pretreatment decreased the locomotor response to amphetamine, the amphetamine-induced increase in dialysate dopamine was unaffected. These results indicate that amphetamine-facilitated dopamine release is independent of neuronal firing and autoreceptor regulation, consistent with the putative accelerative exchange-diffusion mechanism of amphetamine-induced dopamine release. Other possible mechanisms underlying the inhibitory effects of apomorphine on amphetamine locomotor activation are discussed.     

Amphetamine-Induced Dopamine Release in the Rat Striatum: An In Vivo Microdialysis Study

The effects of a number of biochemical and pharmacological manipulations on amphetamine (AMPH)-induced alterations in dopamine (DA) release and metabolism were examined in the rat striatum using the in vivo brain microdialysis method. Basal striatal dialysate concentrations were: DA, 7 nM; dihydroxyphenylacetic acid (DOPAC), 850 nM; homovanillic acid (HVA), 500 nM; 5-hydroxyindoleacetic acid (5-HIAA), 300 nM; and 3-methoxytyramine (3-MT), 3 nM. Intraperitoneal injection of AMPH (4 mg/kg) induced a substantial increase in DA efflux, which attained its maximum response 20-40 min after drug injection. On the other hand, DOPAC and HVA efflux declined following AMPH. The DA response, but not those of DOPAC and HVA, was dose dependent within the range of AMPH tested (2-16 mg/kg). High doses of AMPH (greater than 8 mg/kg) also decreased 5-HIAA and increased 3-MT efflux. Depletion of vesicular stores of DA using reserpine did not affect significantly AMPH-induced dopamine efflux. In contrast, prior inhibition of catecholamine synthesis, using alpha-methyl-p-tyrosine, proved to be an effective inhibitor of AMPH-evoked DA release (less than 35% of control). Moreover, the DA releasing action of AMPH was facilitated in pargyline-pretreated animals (220% of control). These data suggest that AMPH releases preferentially a newly synthesised pool of DA. Nomifensine, a DA uptake inhibitor, was an effective inhibitor of AMPH-induced DA efflux (18% of control). On the other hand, this action of AMPH was facilitated by veratrine and ouabain (200-210% of control). These results suggest that the membrane DA carrier may be involved in the actions of AMPH on DA efflux.     

Effects of Methylphenidate on Extracellular Dopamine, Serotonin, and Norepinephrine: Comparison with Amphetamine

Abstract: Methylphenidate promotes a dose-dependent behavioral profile that is very comparable to that of amphetamine. Amphetamine increases extracellular norepinephrine and serotonin, in addition to its effects on dopamine, and these latter effects may play a role in the behavioral effects of amphetamine-like stimulants. To examine further the relative roles of dopamine, norepinephrine, and serotonin in the behavioral response to amphetamine-like stimulants, we assessed extracellular dopamine and serotonin in caudate putamen and norepinephrine in hippocampus in response to various doses of methylphenidate (10, 20, and 30 mg/kg) that produce stereotyped behaviors, and compared the results with those of a dose of amphetamine (2.5 mg/kg) that produces a level of stereotypies comparable to the intermediate dose of methylphenidate. The methylphenidate-induced changes in dopamine and its metabolites were consistent with changes induced by other uptake blockers, and the magnitude of the dopamine response for a behaviorally comparable dose was considerably less than that with amphetamine. Likewise, the dose-dependent increase in norepinephrine in response to methylphenidate was also significantly less than that with amphetamine. However, in contrast to amphetamine, methylphenidate had no effect on extracellular serotonin. These results do not support the hypothesis that a stimulant-induced increase in serotonin is necessary for the appearance of stereotyped behaviors.     

The Relationship Between the Stimulation of Dopamine Synthesis and Release Produced by Amphetamine and High Potassium in Striatal Slices

The effects of amphetamine (amph) and high K+ on the synthesis and release of dopamine (DA) were compared in striatal slices. Both agents stimulated DA synthesis as well as release. For both agents, Ca2+ was required for the initiation of synthesis stimulation as well as for the maintenance of this stimulation. The addition of EGTA to medium containing slices that were already stimulated by 1.0 microM-amph or 55 mM-K+ markedly reduced the stimulation of DA synthesis. Although it has been reported that high K+ activates soluble tyrosine hydroxylase (TH), neither high K+ nor amph appeared to increase the affinity of the synthetic cofactor, 6-MPH4, or decrease the affinity of the catechol, DA, for TH. This finding was supported by the observation that the inhibitory effect of L-DOPA on DA synthesis in slices, in which synthesis was stimulated by either agent, was not decreased. Although both 1.0 microM-amph and 55 mM-K+ stimulated the release of [3H]DA from striatal slices, the release produced by K+ was Ca2+-dependent, whereas release produced by amph did not occur at any concentration tested. Studies on pH requirements for both synthesis and release also confirmed a similarity between amph and K+ in stimulating synthesis but not in stimulating release. These results suggest that depolarizing agents, such as high K+, couple synthesis and release of DA by a Ca2+-dependent mechanism. In contrast, the simultaneous stimulation of synthesis and release by amph is not regulated by Ca2+.     

Interaction of MIF-I or alpha-MSH with D-amphetamine or chlorpromazine on thermoregulation and motor activity of rats maintained at different ambient temperatures

Administration of several doses of MIF-I or alpha-MSH did not modify colonic temperature or the level of motor activity of rats in ambient temperatures of 4 degree or 20 degrees C. However, the thermoregulatory but not motor effects of the interaction between MIF-I or alpha-MSH with d-amphetamine were dependent upon ambient temperature. At 4 degree C, 1.0 mg/kg of both peptides enhanced the d-amphetamine-induced hypothermia, but at 20 degrees C both peptides blocked the hyperthermic effects of d-amphetamine. The hypothermic effect of chlorpromazine (CPZ) at 4 degree C and 20 degrees C was blocked by 1.0 mg/kg MIF-I but not by 1.0 mg/kg alpha-MSH. No linear dose response relationships between various doses of MIF-I or alpha-MSH and thermal responses were found. Administration of melanin or the use of hypophysectomized rats did not alter the significant interactions observed after peripheral injections.     

Design and synthesis of triarylacrylonitrile analogues of tamoxifen with improved binding selectivity to protein kinase C

The clinical selective estrogen receptor modulator tamoxifen is also a modest inhibitor of protein kinase C, a target implicated in several untreatable brain diseases such as amphetamine abuse. This inhibition and tamoxifen’s ability to cross the blood brain barrier make it an attractive scaffold to conduct further SAR studies toward uncovering effective therapies for such diseases. Utilizing the known compound 6a as a starting template and guided by computational tools to derive physicochemical properties known to be important for CNS permeable drugs, the design and synthesis of a small series of novel triarylacrylonitrile analogues have been carried out providing compounds with enhanced potency and selectivity for PKC over the estrogen receptor relative to tamoxifen. Shortened synthetic routes compared to classical procedures have been developed for analogues incorporating a β-phenyl ring, which involve installing dialkylaminoalkoxy side chains first off the α and/or α′ rings of a precursor benzophenone and then condensing the resultant ketones with phenylacetonitrile anion. A second novel, efficient and versatile route utilizing Suzuki chemistry has also been developed, which will allow for the introduction of a wide range of β-aryl or β-heteroaryl moieties and side-chain substituents onto the acrylonitrile core. For analogues possessing a single side chain off the α- or α′-ring, novel 2D NMR experiments have been carried out that allow for unambiguous assignment of E- and Z-stereochemistry. From the SAR analysis, one compound, 6c, shows markedly increased potency and selectivity for inhibiting PKC with an IC₅₀ of 80 nM for inhibition of PKC protein substrate and >10 μM for binding to the estrogen receptor α (tamoxifen IC₅₀ = 20 μM and 222 nM, respectively). The data on 6c provide support for further exploration of PKC as a druggable target for the treatment of amphetamine abuse.     

Amphetamine-induced changes in immunoreactive NPY in rat brain, pineal gland and plasma

Acute injection of d-amphetamine (10 mg/kg), administered to rats 60 minutes prior to sacrifice, induced a doubling of immunoreactive NPY (NPY-IR) in pineal gland. No changes, however, could be detected in levels of NPY-IR in grossly dissected or microdissected regions of rat brain, nor were changes evident in plasma level concentrations of NPY-IR following acute amphetamine pretreatment. When amphetamine was injected twice daily for six days and once more 60 minutes prior to sacrifice, levels of NPY-IR were decreased in caudate putamen and the paraventricular and dorsomedial nuclei of the hypothalamus, while concentrations of NPY-IR were increased in medial preoptic nucleus, pineal gland, and plasma. These data indicate that levels of NPY-IR are susceptible to manipulation by amphetamine, where the extent and direction of change (increase or decrease) depends on both the frequency of drug administration and the nature of the sampled tissue. Based on the effects of amphetamine on central and peripheral norepinephrine and epinephrine disposition observed in other studies, the data also suggest that NPY-IR and catecholamine dispositions are not directly correlated and may be inversely related in some tissue.     

The Trace Amine 1 receptor knockout mouse: an animal model with relevance to schizophrenia

Trace amines have been implicated in a number of neuropsychiatric disorders including depression and schizophrenia. Although long known to modulate neurotransmission indirectly through the release of catecholamines, the identification of the Trace Amine 1 receptor (TA1) offers a mechanism by which trace amines can influence synaptic activity directly. TA1 binds and is activated by trace amines such as beta-phenylethylamine and tyramine. Our pharmacological characterization of mouse TA1 showed that, as in rat and primate, amphetamine is an agonist at this receptor but with surprisingly high potency. Without selective ligands for TA1 that do not also possess catecholamine-releasing properties, however, it has not been possible to study its physiological role in the central nervous system. To that end, a line of mice lacking the TA1 receptor was generated to characterize its contribution to the regulation of behavior. Compared with wild-type littermates, TA1 knockout (KO) mice displayed a deficit in prepulse inhibition. Knockout animals, in which the TA1-agonist influence of amphetamine was absent, showed enhanced sensitivity to the psychomotor-stimulating effect of this drug, which was temporally correlated with significantly larger increases in the release of both dopamine and norepinephrine in the dorsal striatum and associated with a 262% increase in the proportion of striatal high-affinity D2 receptors. TA1 therefore appears to play a modulatory role in catecholaminergic function and represents a potentially novel mechanism for the treatment of neuropsychiatric disorders. Furthermore, the TA1 KO mouse may provide a useful model for the development of treatments for some positive symptoms of schizophrenia.