The dopamine D2 receptor gene in lamprey, its expression in the striatum and cellular effects of D2 receptor activation

All basal ganglia subnuclei have recently been identified in lampreys, the phylogenetically oldest group of vertebrates. Furthermore, the interconnectivity of these nuclei is similar to mammals and tyrosine hydroxylase-positive (dopaminergic) fibers have been detected within the input layer, the striatum. Striatal processing is critically dependent on the interplay with the dopamine system, and we explore here whether D2 receptors are expressed in the lamprey striatum and their potential role. We have identified a cDNA encoding the dopamine D2 receptor from the lamprey brain and the deduced protein sequence showed close phylogenetic relationship with other vertebrate D2 receptors, and an almost 100% identity within the transmembrane domains containing the amino acids essential for dopamine binding. There was a strong and distinct expression of D2 receptor mRNA in a subpopulation of striatal neurons, and in the same region tyrosine hydroxylase-immunoreactive synaptic terminals were identified at the ultrastructural level. The synaptic incidence of tyrosine hydroxylase-immunoreactive boutons was highest in a region ventrolateral to the compact layer of striatal neurons, a region where most striatal dendrites arborise. Application of a D2 receptor agonist modulates striatal neurons by causing a reduced spike discharge and a diminished post-inhibitory rebound. We conclude that the D2 receptor gene had already evolved in the earliest group of vertebrates, cyclostomes, when they diverged from the main vertebrate line of evolution (560 mya), and that it is expressed in striatum where it exerts similar cellular effects to that in other vertebrates. These results together with our previous published data (Stephenson-Jones et al. 2011, 2012) further emphasize the high degree of conservation of the basal ganglia, also with regard to the indirect loop, and its role as a basic mechanism for action selection in all vertebrates.     

The Dopamine D1-D2 Receptor Heteromer Localizes in Dynorphin/Enkephalin Neurons: INCREASED HIGH AFFINITY STATE FOLLOWING AMPHETAMINE AND IN SCHIZOPHRENIA*

The distribution and function of neurons coexpressing the dopamine D1 and D2 receptors in the basal ganglia and mesolimbic system are unknown. We found a subset of medium spiny neurons coexpressing D1 and D2 receptors in varying densities throughout the basal ganglia, with the highest incidence in nucleus accumbens and globus pallidus and the lowest incidence in caudate putamen. These receptors formed D1-D2 receptor heteromers that were localized to cell bodies and presynaptic terminals. In rats, selective activation of D1-D2 heteromers increased grooming behavior and attenuated AMPA receptor GluR1 phosphorylation by calcium/calmodulin kinase IIα in nucleus accumbens, implying a role in reward pathways. D1-D2 heteromer sensitivity and functional activity was up-regulated in rat striatum by chronic amphetamine treatment and in globus pallidus from schizophrenia patients, indicating that the dopamine D1-D2 heteromer may contribute to psychopathologies of drug abuse, schizophrenia, or other disorders involving elevated dopamine transmission.     

Dopamine Metabolism and Receptor Function After Acute and Chronic Ethanol

Abstract: Acute ethanol treatment in rats elicits a selective increase in dihydroxyphenylacetic acid (DOPAC) content in striatum. In contrast, striatal DOPAC concentration does not differ from normal values after chronic ethanol treatment. Chronic administration of ethanol however causes a selective increase of specific [3H]spiroperidol binding and met-enkephalin content in the striatum. Kinetic analysis of [3H]spiroperidol binding data shows that after chronic ethanol treatment there is a significant increase in the affinity constant rather than in the number of binding sites for the ligand. Our results support the hypothesis that dopaminergic mechanisms at both pre- and postsynaptic level may be involved in the mediation of some of the central effects observed after ethanol consumption.     

Long-term administration of cocaine or serotonin reuptake inhibitors results in anatomical and neurochemical changes in noradrenergic, dopaminergic, and serotonin pathways

The catechol and indole pathways are important components underlying plasticity in the frontal cortex and basal ganglia. This study demonstrates that administering rats either cocaine or a selective serotonin (or 5-hydroxytryptamine; 5-HT) reuptake inhibitor (SSRI) for 16 weeks results in reduced density of dopaminergic and noradrenergic terminals in the striatum and olfactory bulb, respectively, reflecting pruning of the terminal arbor of ventral midbrain dopaminergic and locus coeruleus noradrenergic neurones. In the striatum of cocaine-treated animals, basal dopamine levels, as well as cocaine-induced dopamine release, is diminished compared with controls. In contrast, serotonergic fibers, projecting from the raphe, sprout and have increased terminal density in the lateral septal nucleus and frontal cortex, following long-term cocaine or SSRI treatment. This is associated with elevated basal 5-HT and enhanced cocaine-induced 5-HT release in the frontal cortex. The anatomical and neurochemical changes in serotonergic fibers following cocaine or SSRI treatment may be explained by attenuated 5-HT_1A autoreceptor function in the raphe. This study demonstrates extensive plasticity in the morphology and neurochemistry of the catechol and indole pathways that contribute to drug-induced plasticity of the corticostriatal (and other) projections. Moreover, our data suggest that drug-induced plastic adaptation is anatomically widespread and consequently, likely to have multiple and complex consequences.     

Distinct responses of basal ganglia substance P systems to low and high doses of methamphetamine

Substance P (SP) is a neuropeptide closely associated with basal ganglia dopaminergic neurons. Because some neuropeptide systems in the basal ganglia (i.e. neurotensin and metenkephalin) are differentially affected by treatment with low or high doses of methamphetamine, we determined if basal ganglia SP pathways were also differentially influenced in a dose-dependent manner by this psychostimulant. Employing in vivo microdialysis, it was observed that the low dose (0.5 mg/kg) of methamphetamine increased the extracellular concentration of SP in the substantia nigra, but not in globus pallidus or striatum. In contrast, the high dose (10 mg/kg) of methamphetamine did not increase extracellular SP content in any of these structures. The effect of the low-dose methamphetamine treatment on nigral extracellular SP levels was blocked by pre-treatment with either a D1 or D2 antagonist. In addition, 12 h after similar methamphetamine treatments, a dose-dependent differential response in SP tissue levels occurred in some of the regions examined. When these changes occurred, the low dose of methamphetamine usually reduced, whereas the high dose increased, SP tissue content. This study demonstrated opposite responses of the basal ganglia SP system to low and high doses of methamphetamine and suggested that a combination of dopamine D1 and D2 receptor activity contributed to these effects.     

High-and Low-Affinity States of Striatal D2 Receptors Are Not Affected by 6-Hydroxydopamine or Chronic Haloperidol Treatment

Specific D2 binding in rat striatum was characterized and then the effects of chronic disruption of dopaminergic activity on antagonist and agonist binding to these sites were studied. D2 receptors were defined as those sites capable of binding [3H]spiperone in the presence of cinanserin, a 5-HT2 antagonist, but not in the presence of (+)-butaclamol, a D2 and 5-HT2 blocker. Saturation, competition, and kinetic analyses suggested that D2 receptors are a homogeneous population exhibiting more complex interactions with agonists than antagonists. Antagonist binding was monophasic and guanine nucleotide-insensitive whereas agonist binding was biphasic and guanine nucleotide-sensitive. D2 receptor density was elevated by more than 40% following dopamine depletion by 6-hydroxydopamine or chronic receptor blockade by haloperidol. However neither treatment altered the affinities or magnitudes of the high- and low-affinity components associated with agonist binding to the D2 receptor.     

Neuroadaptations to hyperdopaminergia in dopamine D3 receptor-deficient mice

The dopamine D3 receptor (D3R) has been implicated in schizophrenia, drug addiction, depression and Parkinson's disease. The D3R is localized post-synaptically on nucleus accumbens neurons, but is also an autoreceptor on dopaminergic neurons in the mesencephalon. Its functional role as autoreceptor is highly debated, but supported by the elevated basal extracellular dopamine levels found in D3R-deficient mice. To investigate the functional role of the D3R in vivo, we used mice with a targeted disruption of the D3R gene. We found a higher basal level of grooming in D3R-deficient mice, compared to their wild-type littermates. This behavior, which is under the control of D1R stimulation, may be related to an increased dopaminergic tone, since no changes in the gene expression of dopamine D1 and D2 receptors were noticed in the striatum of these mice. D3R-deficient mice displayed other neuroadaptive changes, including decreased tyrosine hydroxylase, increased dopamine transporter mRNAs and increased dopamine reuptake in striatum. The level of tyrosine hydroxylase protein was unchanged in the striatum, as preprodynorphin and preproenkephalin gene expressions. All the changes identified in D3R-deficient mice cannot explain hyperdopaminergia, but, on the contrary, tend to attenuate this phenotype. These results support a distinct role for D2R and D3R as autoreceptors: the D2R is the release-regulating and firing rate-regulating autoreceptor, whereas the D3R may control basal dopamine levels in the striatum, by an unknown mechanism, which does not involve regulation of dopamine transporters or tyrosine hydroxylase. This hyperdopaminergia phenotype of D3R-deficient mice may explain their hyperactivity to drug-paired environmental cues.     

Change of dopamine, serotonin and opioid neuromediator systems in the brain of rats adapted to prolonged effect of ethanol

AIM OF THE STUDY: To investigate the effect of in vivo short-term ethanol administration (i.p., 1.5 g/kg, 6 h) on binding characteristics of opioid receptor agonists in rat midbrain, as well as the contents of dopamine, serotonin and their precursors and metabolites in midbrain, striatum and hypothalamus of rats after long-term alcohol consumption. The methods of receptor binding assay and high performance liquid chromatography with electrochemical detection were used. The data obtained suggest that the response of neurotransmitter systems to short-term ethanol administration in different regions of rats brain is not identical. Our findings demonstrate that short-term ethanol administration may modulate dopaminergic transmission in the rat hypothalamus and striatum but this effect may be attenuated by down-regulation of OP, in the midbrain after long-term alcohol consumption. Serotonin system in hypothalamus becomes more sensitive to short-term ethanol administration after the long-term ethanol-containing liquid diet in comparison with control rats. Our results suggest that reinforcing properties of ethanol may be partially mediated by mechanisms involving the ethanol-induced disturbing of dopaminergic metabolism in the midbrain and hypothalamus and serotoninergic metabolism in hypothalamus.     

Effects of alloxan-induced diabetes on dopaminergic receptors in rat striatum and anterior pituitary

The binding of [3H]-spiroperidol after 4 weeks of hyperglycemia was determined in the rat striatum and anterior pituitary. Alloxan-induced diabetes increased the number of dopaminergic binding sites in the striatum but not in the anterior pituitary. The interaction of metoclopramide with striatal dopaminergic receptors was slightly modified, while that of dopamine, bromocriptine and haloperidol was unaffected. These results suggest that chronic hyperglycemia exerts selective effects on nigrostriatal dopaminergic system in the rat.     

Relationship of calmodulin and dopaminergic activity in the striatum

Increasing evidence suggests a relationship between dopaminergic activity in the striatum and the content of calmodulin (CaM), an endogenous Ca2+-binding protein. The content of CaM in striatal membranes is increased by treatments that produce supersensitivity in striatal membranes is increased by treatments that produce supersensitivity of striatal dopaminergic receptors such as chronic neuroleptic treatment or injection of 6-hydroxydopamine. Concomitant with the increase in CaM is a greater sensitivity of adenylate cyclase to dopamine and an increase in Ca2+-sensitive phosphorylation in the striatal membranes. Procedures that result in dopaminergic subsensitivity, such as amphetamine treatment, increase the cytosolic content of CaM that can subsequently activate Ca2+ and CaM-dependent phosphodiesterase activity. In vitro studies have demonstrated that CaM and Ca2+ can stimulate basal adenylate cyclase activity in a striatal particulate fraction as well as increase the sensitivity of the enzyme to dopamine. Ca2+ and CaM most likely affect the dopamine-sensitive adenylate cyclase by interacting with guanyl nucleotides, which are required for dopamine sensitivity. It is concluded that a change in CaM concentration and/or location occurs during conditions of altered dopaminergic sensitivity in the striatum. These changes in CaM coupled with potential alterations in the Ca2+ concentration could modulate the sensitivity of the dopamine system and many CaM-dependent enzymes.     

Characterization and localization of D1 dopamine receptors in the sexually dimorphic vocal control nucleus,area X,and the basal ganglia of european starlings

D1 dopamine receptors were pharmacologically characterized and localized by quantitative autoradiography in the basal ganglia of male and female European starlings (Sturnus vulgaris). The D1 selective antagonist SCH 23390 was used to label this receptor subtype. Starlings are songbirds and possess a neural circuit implicated in the learning and production of song. This circuit includes a sexually dimorphic nucleus, area X, that is a subregion of the parolfactory lobe of the basal ganglia and is known from work on zebra finches to receive dopaminergic input from the area ventralis of Tsai. We focused our investigation on the D1-like receptor subtype because they are abundant in the basal ganglia. Competition studies indicate that a variety of dopaminergic ligands compete with [³H] SCH 23390 for the binding site in an order of potency characteristic of a D1-like receptor. Autoradiographic studies of the basal ganglia revealed high D1 receptor densities in the avian homologues of the caudate-putamen and relatively low-receptor densities were observed in the avian homologue of the globus pallidus. In male starlings, area X could be reliably discerned on the autoradiograms by the higher density of D1 receptors compared to the surrounding parolfactory lobe (LPO). This was also true for females, though nt as reliably as in males. When we compared the mean D1 receptor density in area X for males and females we did not find a significant sex difference. However, we also analyzed the data by comparing sex differences in the degree to which area X has a higher receptor density in comparison with the surrounding LPO. When we normalized D1 receptor density in area X relative to the LPO, we did find a significant sex difference. This sex difference in relative receptor density represents another neural sex difference in the song circuit that may mediate sex differences in the learning and production of song in starlings and other songbirds. 1994 John Wiley & Sons, Inc.     

Temporal Changes of CB1 Cannabinoid Receptor in the Basal Ganglia as a Possible Structure-Specific Plasticity Process in 6-OHDA Lesioned Rats

The endocannabinoid system has been implicated in several neurobiological processes, including neurodegeneration, neuroprotection and neuronal plasticity. The CB1 cannabinoid receptors are abundantly expressed in the basal ganglia, the circuitry that is mostly affected in Parkinson’s Disease (PD). Some studies show variation of CB1 expression in basal ganglia in different animal models of PD, however the results are quite controversial, due to the differences in the procedures employed to induce the parkinsonism and the periods analyzed after the lesion. The present study evaluated the CB1 expression in four basal ganglia structures, namely striatum, external globus pallidus (EGP), internal globus pallidus (IGP) and substantia nigra pars reticulata (SNpr) of rats 1, 5, 10, 20, and 60 days after unilateral intrastriatal 6-hydroxydopamine injections, that causes retrograde dopaminergic degeneration. We also investigated tyrosine hydroxylase (TH), parvalbumin, calbindin and glutamic acid decarboxylase (GAD) expression to verify the status of dopaminergic and GABAergic systems. We observed a structure-specific modulation of CB1 expression at different periods after lesions. In general, there were no changes in the striatum, decreased CB1 in IGP and SNpr and increased CB1 in EGP, but this increase was not sustained over time. No changes in GAD and parvalbumin expression were observed in basal ganglia, whereas TH levels were decreased and the calbindin increased in striatum in short periods after lesion. We believe that the structure-specific variation of CB1 in basal ganglia in the 6-hydroxydopamine PD model could be related to a compensatory process involving the GABAergic transmission, which is impaired due to the lack of dopamine. Our data, therefore, suggest that the changes of CB1 and calbindin expression may represent a plasticity process in this PD model.     

Neurotransmitter function in the basal ganglia after acute and chronic ethanol treatment

Acute and chronic administration of ethanol has multiple effects on several neurotransmitters in the basal ganglia. Dopamine is the transmitter predominantly affected. Acceleration of dopaminergic activity is observed at low doses of ethanol. However, at high doses the reverse is observed. During the ethanol withdrawal syndrome that develops after chronic treatment, dopaminergic responses are reduced, whether from presynaptic or postsynaptic origins. Evidence also indicates that cholinergic and GABAergic processes may be implicated in these actions of ethanol. Ethanol apparently induces a variety of alterations in neurotransmitter function as a result of its disruption of membrane structure and associated electric properties.     

Extended access to cocaine self-administration results in reduced glutamate function within the medial prefrontal cortex

Previous studies have shown that brief access to cocaine yields an increase in D2 receptor binding in the medial prefrontal cortex (mPFC), but that extended access to cocaine results in normalized binding of D2 receptors (i.e. the D2 binding returned to control levels). Extended-access conditions have also been shown to produce increased expression of the NR2 subunit of the N-Methyl-D-aspartate receptor in the mPFC. These results implicate disrupted glutamate and dopamine function within this area. Therefore, in the present study, we monitored glutamate and dopamine content within the mPFC during, or 24 hours after, cocaine self-administration in animals that experienced various amounts of exposure to the drug. Na?ve subjects showed decreased glutamate and increased dopamine levels within the mPFC during cocaine self-administration. Exposure to seven 1-hour daily cocaine self-administration sessions did not alter the response to self-administered cocaine, but resulted in decreased basal dopamine levels. While exposure to 17 1-hour sessions also resulted in reduced basal dopamine levels, these animals showed increased dopaminergic, but completely diminished glutamatergic, response to self-administered cocaine. Finally, exposure to 17 cocaine self-administration sessions, the last 10 of which being 6-hour sessions, resulted in diminished glutamatergic response to self-administered cocaine and reduced basal glutamate levels within the mPFC while normalizing (i.e. causing a return to control levels) both the dopaminergic response to self-administered cocaine as well as basal dopamine levels within this area. These data demonstrate directly that the transition to escalated cocaine use involves progressive changes in dopamine and glutamate function within the mPFC.     

Methylphenidate alters basal ganglia neurotensin systems through dopaminergic mechanisms: a comparison with cocaine treatment

Methylphenidate (MPD) is a psychostimulant widely used to treat behavioral problems such as attention deficit hyperactivity disorder. MPD competitively inhibits the dopamine (DA) transporter. Previous studies demonstrated that stimulants of abuse, such as cocaine (COC) and methamphetamine differentially alter rat brain neurotensin (NT) systems through DA mechanisms. As NT is a neuropeptide primarily associated with the regulation of the nigrostriatal and mesolimbic DA systems, the effect of MPD on NT-like immunoreactivity (NTLI) content in several basal ganglia regions was assessed. MPD, at doses of 2.0 or 10.0 mg/kg, s.c., significantly increased the NTLI contents in dorsal striatum, substantia nigra and globus pallidus; similar increases in NTLI were observed in these areas after administration of COC (30.0 mg/kg, i.p.). No changes in NTLI occurred within the nucleus accumbens, frontal cortex and ventral tegmental area following MPD treatment. In addition, the NTLI changes in basal ganglia regions induced by MPD were prevented when D(1) (SCH 23390) or D(2) (eticlopride) receptor antagonists were coadministered with MPD. MPD treatment also increased dynorphin (DYN) levels in basal ganglia structures. These findings provide evidence that basal ganglia, but not limbic, NT systems are significantly affected by MPD through D(1) and D(2) receptor mechanisms, and these NTLI changes are similar, but not identical to those which occurred with COC administration. In addition, the MPD effects on NT systems are mechanistically distinct from the effects of methamphetamine.     

EFFECTS OF ELECTRICAL STIMULATION OF THE NIGROSTRIATAL PATHWAY OF THE RAT ON DOPAMINE METABOLISM

Abstract— Electrical stimulation of the nigrostriatal dopaminergic pathway in rat brain elicited a frequency and current intensity-dependent increased in the formation of homovanillic acid in the basal ganglia. The accumulation of the acid in probenecid-treated animals was constant over 1 h, when maximally stimulated at 25 Hz and 300 μA. Dopamine levels remained unchanged during stimulation. When prior to stimulation the inhibitor of catecholamine synthesis α-methyl- p -tyrosine methyl ester was administered, dopamine levels declined biphasically. Tyrosine and nomifensine, a dopamine uptake inhibitor, and apomorphine had no major effect on the formation of homovanillic acid, whilst α-methyl- p -tyrosine prevented its formation. Our data suggest that dopamine in the striatum is compartmentalized and that the newly-synthesized amine is released and converted to homovanillic acid. Apomorphine decreases dopamine flux only when dopaminergic neurons are at rest. When depolarized neither access of the precursor nor reuptake seem to influence the conversion of dopamine to homovanillic acid.     

Human immunodeficiency virus-1 Tat protein and methamphetamine interact synergistically to impair striatal dopaminergic function

The human immunodeficiency virus (HIV)-1 transactivating protein Tat may be pathogenically relevant in HIV-1-induced neuronal injury. The abuse of methamphetamine (MA), which is associated with behaviors that may transmit HIV-1, may damage dopaminergic afferents to the striatum. Since Tat and MA share common mechanisms of injury, we examined whether co-exposure to these toxins would lead to enhanced dopaminergic toxicity. Animals were treated with either saline, a threshold dose of MA, a threshold concentration of Tat injected directly into the striatum, or striatal injections of Tat followed by exposure to MA. Threshold was defined as the highest concentration of toxin that would not result in a significant loss of striatal dopamine levels. One week later, MA-treated animals demonstrated a 7% decline in striatal dopamine levels while Tat-treated animals showed an 8% reduction. Exposure to both MA + Tat caused an almost 65% reduction in striatal dopamine. This same treatment caused a 56% reduction in the binding capacity to the dopamine transporter. Using human fetal neurons, enhanced toxicity was also observed when cells were exposed to both Tat and MA. Mitochondrial membrane potential was disrupted and could be prevented by treatment with antioxidants. This study demonstrates that the HIV-1 'virotoxin' Tat enhances MA-induced striatal damage and suggests that HIV-1-infected individuals who abuse MA may be at increased risk of basal ganglia dysfunction.     

CB1-independent inhibition of dopamine transporter activity by cannabinoids in mouse dorsal striatum

Cannabinoid drugs are known to affect dopaminergic neurotransmission in the basal ganglia circuitry. In this study, we used in vitro and in vivo techniques to investigate whether cannabinoid agonists and antagonist could affect dopaminergic transmission in the striatum by acting at the dopamine transporter. Incubation of striatal synaptosomes with the cannabinoid agonists WIN55,212-2 or methanandamide decreased dopamine uptake (IC(50) = 2.0 micromol/L and 3.1 micromol/L, respectively). A similar inhibitory effect was observed after application of the inactive WIN55,212-2 isomer, S(-)WIN55,212-3. The CB(1) antagonist AM251 did not reverse WIN55,212-2 effect but rather mimicked it. WIN55,212-2 and AM251 partially displaced the binding of the cocaine analog [(3)H]WIN35,428, thus acting as dopamine transporter pseudo-substrates in the high micromolar range. High-speed chronoamperometry measurements showed that WIN55,212-2 (4 mg/kg, i.p.) caused significant release of endogenous dopamine via activation of CB(1) receptors, followed by a reduction of dopamine clearance. This reduction was CB(1)-independent, as it was mimicked by S(-)WIN55,212-3. Administration of AM251 (1 and 4 mg/kg, i.p.) increased the signal amplitude and reduced the clearance of dopamine pressure ejected into the striatum. These results indicate that both cannabinoid agonists and antagonists inhibit dopamine transporter activity via molecular targets other than CB(1) receptors.     

Dopamine-dependent ectodomain shedding and release of epidermal growth factor in developing striatum: target-derived neurotrophic signaling (Part 2)

Epidermal growth factor (EGF) and structurally related peptides promote neuronal survival and the development of midbrain dopaminergic neurons; however, the regulation of their production has not been fully elucidated. In this study, we found that the treatment of striatal cells with dopamine agonists enhances EGF release both in vivo and in vitro. We prepared neuron-enriched and non-neuronal cell-enriched cultures from the striatum of rat embryos and challenged those with various neurotransmitters or dopamine receptor agonists. Dopamine and a dopamine D(1) -like receptor agonist (SKF38393) triggered EGF release from neuron-enriched cultures in a dose-dependent manner. A D(2) -like agonist (quinpirole) increased EGF release only from non-neuronal cell-enriched cultures. The EGF release from striatal neurons and non-neuronal cells was concomitant with ErbB1 phosphorylation and/or with the activation of a disintegrin and metalloproteinase and matrix metalloproteinase. The EGF release from neurons was attenuated by an a disintegrin and metalloproteinase/matrix metalloproteinase inhibitor, GM6001, and a calcium ion chelator, BAPTA/AM. Transfection of cultured striatal neurons with alkaline phosphatase-tagged EGF precursor cDNA confirmed that dopamine D(1) -like receptor stimulation promoted both ectodomain shedding of the precursor and EGF release. Therefore, the activation of striatal dopamine receptors induces shedding and release of EGF to provide a retrograde neurotrophic signal to midbrain dopaminergic neurons.     

mTORC1 signaling in Parkinson disease and L-DOPA-induced dyskinesia: A sensitized matter

Parkinson's disease is caused by the progressive loss of dopamine innervation to the basal ganglia and is commonly treated with the dopamine precursor, L-DOPA. Prolonged administration of L-DOPA results in the development of severe motor complications, or dyskinesia, which seriously hamper its clinical use. Recent evidence indicates that L-DOPA-induced dyskinesia (LID) is associated with persistent activation of the mammalian target of rapamycin complex 1 (mTORC1) in the medium spiny neurons (MSNs) of the striatum, the main component of the basal ganglia. This phenomenon is secondary to the development of a strong sensitization at the level of dopamine D1 receptors, which are abundantly expressed in a subset of MSNs. Such sensitization confers to dopaminergic drugs (including L-DOPA) the ability to activate the extracellular signal-regulated protein kinases 1/2, which, in turn promote mTORC1 signaling. Using a mouse model of LID, we recently showed that administration of the allosteric mTORC1 inhibitor, rapamycin, reduces dyskinesia. This finding is discussed with respect to underlying mechanisms and potential significance for the development of future therapeutic interventions.