Ana B. Martín

ERK Phosphorylation and FosB Expression Are Associated with L-DOPA-Induced Dyskinesia in Hemiparkinsonian Mice

BACKGROUND The dopamine precursor 3,4-dihydroxyphenyl-L-alanine (L-DOPA) is currently the most efficacious noninvasive therapy for Parkinsons disease. A major complication of this therapy, however, is the appearance of the abnormal involuntary movements known as dyskinesias. We have developed a model of L-DOPA-induced dyskinesias in mice that reproduces the main clinical features of dyskinesia in humans. METHODS Dyskinetic symptoms were triggered by repetitive administration of a constant dose of L-DOPA (25 mg/kg, twice a day, for 25 days) in unilaterally 6-hydroxydopamine (6-OHDA) lesioned mice. Mice were examined for behavior, expression of FosB, neuropeptides, and externally regulated kinase (ERK) phosphorylation. RESULTS Dyskinetic symptoms appear toward the end of the first week of treatment and are associated with L-DOPA-induced changes in DeltaFosB and prodynorphin expression. L-DOPA also induces activation of ERK1/2 in the dopamine-depleted striatum. Interestingly, elevated FosB/DeltaFosB expression occurs exclusively within completely lesioned regions of the striatum, displaying an inverse correlation with remaining dopaminergic terminals. Following acute L-DOPA treatment, FosB expression occurs in direct striatal output neurons, whereas chronic L-DOPA also induces FosB expression in nitric oxide synthase-positive striatal interneurons. CONCLUSIONS This model provides a system in which genetic manipulation of individual genes can be used to elucidate the molecular mechanisms responsible for the development and expression of dyskinesia.

Receptor subtypes involved in the presynaptic and postsynaptic actions of dopamine on striatal interneurons

By stimulating distinct receptor subtypes, dopamine (DA) exerts presynaptic and postsynaptic actions on both large aspiny (LA) cholinergic and fast-spiking (FS) parvalbumin-positive interneurons of the striatum. Lack of receptor- and isoform-specific pharmacological agents, however, has hampered the progress toward a detailed identification of the specific DA receptors involved in these actions. To overcome this issue, in the present study we used four different mutant mice in which the expression of specific DA receptors was ablated. In D1 receptor null mice, D1R-/-, DA dose-dependently depolarized both LA and FS interneurons. Interestingly, SCH 233390 (10 μm), a D1-like (D1 and D5) receptor antagonist, but not l-sulpiride (3–10 μm), a D2-like (D2, D3, D4) receptor blocker, prevented this effect, implying D5 receptors in this action. Accordingly, immunohistochemical analyses in both wild-type and D1R-/- mice confirmed the expression of D5 receptors in both cholinergic and parvalbumin-positive interneurons of the striatum. In mice lacking D2 receptors, D2R-/-, the DA-dependent inhibition of GABA transmission was lost in both interneuron populations. Both isoforms of D2 receptor, D2L and D2S, were very likely involved in this inhibitory action, as revealed by the electrophysiological analysis of the effect of the DA D2-like receptor agonist quinpirole in two distinct mutants lacking D2L receptors and expressing variable contents of D2S receptors. The identification of the receptor subtypes involved in the actions of DA on different populations of striatal cells is essential to understand the circuitry of the basal ganglia and to develop pharmacological strategies able to interfere selectively with specific neuronal functions.

Genetic Inactivation of Dopamine D1 but Not D2 Receptors Inhibits L-DOPA–Induced Dyskinesia and Histone Activation

BACKGROUND Pharmacologic studies have implicated dopamine D1-like receptors in the development of dopamine precursor molecule 3,4-dihydroxyphenyl-L-alanine (L-DOPA)-induced dyskinesias and associated molecular changes in hemiparkinsonian mice. However, pharmacologic agents for D1 or D2 receptors also recognize other receptor family members. Genetic inactivation of the dopamine D1 or D2 receptor was used to define the involvement of these receptor subtypes. METHODS During a 3-week period of daily L-DOPA treatment (25 mg/kg), mice were examined for development of contralateral turning behavior and dyskinesias. L-DOPA-induced changes in expression of signaling molecules and other proteins in the lesioned striatum were examined immunohistochemically. RESULTS Chronic L-DOPA treatment gradually induced rotational behavior and dyskinesia in wildtype hemiparkinsonian mice. Dyskinetic symptoms were associated with increased FosB and dynorphin expression, phosphorylation of extracellular signal-regulated kinase, and phosphoacetylation of histone 3 (H3) in the lesioned striatum. These molecular changes were restricted to striatal areas with complete dopaminergic denervation and occurred only in dynorphin-containing neurons of the direct pathway. D1 receptor inactivation abolished L-DOPA-induced dyskinesias and associated molecular changes. Inactivation of the D2 receptor had no significant effect on the behavioral or molecular response to chronic L-DOPA. CONCLUSIONS Our results demonstrate that the dopamine D1 receptor is critical for the development of L-DOPA-induced dyskinesias in mice and in the underlying molecular changes in the denervated striatum and that the D2 receptor has little or no involvement. In addition, we demonstrate that H3 phosphoacetylation is blocked by D1 receptor inactivation, suggesting that inhibitors of H3 acetylation and/or phosphorylation may be useful in preventing or reversing dyskinesia.

Neuroanatomical relationship between type 1 cannabinoid receptors and dopaminergic systems in the rat basal ganglia

Dopamine and endocannabinoids are neurotransmitters known to play a role in the activity of the basal ganglia motor circuit. While a number of studies have demonstrated functional interactions between type 1 cannabinoid (CB1) receptors and dopaminergic systems, we still lack detailed neuroanatomical evidence to explain their relationship. Single- and double-labeling methods (in situ hybridization and immunohistochemistry) were employed to determine both the expression and localization of CB1 receptors and tyrosine hydroxylase (TH) in the basal ganglia. In the striatum, we found an intense signal for CB1 receptor transcripts but low signal for CB1 receptor protein, whereas in the globus pallidus and substantia nigra we found the opposite; no hybridization signal but intense immunoreactivity. Consequently, CB1 receptors are synthesized in the striatum and mostly transported to its target areas. No co-expression or co-localization of CB1 receptors and TH was found. In the caudate-putamen, globus pallidus and substantia nigra, TH-immunoreactive fibers were interwoven with the CB1 receptor-immunoreactive neuropil and fibers. Our data suggest that the majority of the striatal CB1 receptors are located presynaptically on inhibitory GABAergic terminals, in a position to modulate neurotransmitter release and influence the activity of substantia nigra dopaminergic neurons. In turn, afferent dopaminergic fibers from the substantia nigra innervate CB1 receptor-expressing striatal neurons that are known to also express dopamine receptors. In conclusion, these data provide a neuroanatomical basis to explain functional interactions between endocannabinoid and dopaminergic systems in the basal ganglia.

Expression and Function of CB1 Receptor in the Rat Striatum: Localization and Effects on D1 and D2 Dopamine Receptor-Mediated Motor Behaviors

Cannabinoid CB1 receptors are densely expressed on striatal projection neurons expressing dopamine D1 or D2 receptors. However, the specific neuronal distribution of CB1 receptors within the striatum is not known. Previous research has established that the endocannabinoid system controls facilitation of behavior by dopamine D2 receptors, but it is not clear if endocannabinoids also modulate D1 receptor-mediated motor behavior. In the present study, we show that cannabinoid CB1 receptor mRNA is present in striatonigral neurons expressing substance P and dopamine D1 receptors, as well as in striatopallidal neurons expressing enkephalin and dopamine D2 receptors. We explored the functional relevance of the interaction between dopamine D1 and D2 receptors and cannabinoid CB1 receptors with behavioral pharmacology experiments. Potentiation of endogenous cannabinoid signaling by the uptake blocker AM404 blocked dopamine D1 receptor-mediated grooming and D2 receptor-mediated oral stereotypies. In addition, contralateral turning induced by unilateral intrastriatal infusion of D1 receptor agonists is counteracted by AM404 and potentiated by the cannabinoid antagonist SR141716A. These results indicate that the endocannabinoid system negatively modulates D1 receptor-mediated behaviors in addition to its previously described effect on dopamine D2 receptor-mediated behaviors. The effect of AM404 on grooming behavior was absent in dopamine D1 receptor knockout mice, demonstrating its dependence on D1 receptors. This study indicates that the endocannabinoid system is a relevant negative modulator of both dopamine D1 and D2 receptor-mediated behaviors, a finding that may contribute to our understanding of basal ganglia motor disorders.

Molecular phenotype of rat striatal neurons expressing the dopamine D5 receptor subtype

Dopamine is one of the principal neurotransmitters in the basal ganglia, where it plays a critical role in motor control and cognitive function through its interactions with the specific dopamine receptors D1 to D5. Although the activities mediated by most dopamine receptor subtypes have already been determined, the role of the D5 receptor subtype in the basal ganglia has still not been established. Furthermore, it is often difficult to distinguish between dopamine D5 and D1 receptors as they are stimulated by the same ligands, and they have a similar molecular structure and pharmacology. In an effort to understand the differences between these two receptor subtypes, we have studied the distribution of neurons containing D5 receptors in the striatum, and their molecular phenotype. As a result, we show that the D5 receptor subtype is present in two different populations of striatal neurons, projection neurons and interneurons. Overall, the abundance of this receptor subtype in the striatum is low, particularly in striatal projection neurons of both the direct and indirect projection pathways. In contrast, the expression of D5 receptors in striatal interneurons (cholinergic, somatostatin‐ or parvalbumin‐positive neurons) is high, while low to moderate expression was observed in calretinin‐positive neurons. Our results demonstrate the presence of D5 receptors in all the striatal cell populations so far described, although at different intensities in each. The fact that a large number of striatal neurons express the D5 receptor subtype suggests that this receptor fulfils an important function in the process of integrating information in the striatum.

Inactivation of adenosine A2A receptors selectively attenuates amphetamine-induced behavioral sensitization

Repeated treatment with the psychostimulant amphetamine produces behavioral sensitization that may represent the neural adaptations underlying some features of psychosis and addiction in humans. In the present study we investigated the role of adenosine A2A receptors in psychostimulant-induced locomotor sensitization using an A2A receptor knockout (A2A KO) model. Daily treatment with amphetamine for 1 week resulted in an enhanced motor response on day 8 (by two-fold compared to that on day 1), and remained enhanced at day 24 upon rechallenge with amphetamine. By contrast, locomotor sensitization to daily amphetamine did not develop in A2A KO mice on day 8 or 24, and this absence was not the result of a nonspecific threshold effect. The absence of behavioral sensitization was selective for amphetamine since daily treatment with the D1 agonist SKF81297 (2.5 mg/kg) or the D2 agonist quinpirole (1.0 mg/kg) produced similar behavioral sensitization in both WT and A2A KO mice. Furthermore, coinjection of SKF81297 and quinpirole also resulted in indistinguishable locomotor sensitization in A2A KO and WT mice, suggesting normal D1 and D2 receptor responsiveness. Finally, at the cellular level A2A receptor inactivation abolished the increase in striatal dynorphin mRNA induced by repeated amphetamine administration. The selective absence of amphetamine-induced behavioral sensitization in A2A KO mice suggests a critical role of the A2A receptor in the development of psychostimulant-induced behavioral sensitization, and supports the pharmacological potential of A2A adenosinergic agents to modulate adaptive responses to repeated psychostimulant exposure.

Endogenous dopamine amplifies ischemic long-term potentiation via D1 receptors

Background and Purpose— Several observations indicate that, during energy deprivation, endogenous dopamine may become neurotoxic. Accordingly, the nucleus striatum is a preferential site of silent infarcts in humans, and experimental ischemia caused by homolateral carotid occlusion selectively damages this dopamine-enriched brain area. In an attempt to clarify how dopamine takes part in ischemia-induced neuronal damage, we performed in vitro electrophysiological recordings from neurons of the nucleus striatum. Methods— Intracellular recordings with sharp microelectrodes were performed from corticostriatal slices. Slices were obtained from both rats and wild-type and dopamine D1 receptor-lacking mice. In some experiments, the striatum was unilaterally denervated by injecting the dopamine-specific neurotoxin 6-hydroxydopamine in the homolateral substantia nigra. Dopamine agonists and antagonists, as well as drugs targeting the intracellular cascade coupled to dopamine receptor stimulation, were applied at known concentrations. Results— Manipulation of the dopamine system failed to affect the membrane depolarization of striatal neurons exposed to combined oxygen and glucose deprivation of short duration, but it reduced the amplitude of postischemic long-term potentiation (LTP) expressed at corticostriatal synapses. In particular, pharmacological blockade or genetic inactivation of D1/cAMP/protein kinase A pathway prevented the long-term increase of the excitatory postsynaptic potential (EPSP) amplitude caused by a transient ischemic episode, while it failed to prevent the increase of the EPSP half-decay coupled to ischemic LTP. Conclusions— The present data suggest that endogenous dopamine, via D1 receptors, selectively facilitates the expression of ischemic LTP on the AMPA-mediated component of the EPSPs, while it does not alter the expression of this form of synaptic plasticity on the N-methyl-d-aspartate-mediated component of corticostriatal synaptic potentials. Understanding the cellular and molecular mechanisms of ischemia-triggered excitotoxicity offers hope for the development of specific treatments able to interfere with this pathological process.

Molecular dissection of dopamine receptor signaling

The use of genetically engineered mice has provided substantial new insights into the functional organization of the striatum. Increasing evidence suggests that specific genes expressed within the striatum contribute to its functional activity. We studied the dopamine (DA) D1 receptor gene and one of its downstream targets, the transcription factor c-Fos. We have evaluated the functional interaction between the D1 and D2 DA receptor subtypes at the cellular and behavioral levels. Our results show that haloperidol, a DA D2-class receptor antagonist, activates c-Fos predominantly in enkephalin-positive striatal neurons, which project to the globus pallidus and are thought to mediate motor inhibition. Deletion of the DA D1 receptor increased the responsiveness of enkephalin neurons to haloperidol, in that haloperidol-induced increases in c-Fos and catalepsy were enhanced in D1 receptor knockout mice. These results suggest a functionally opposing role of the D1 receptor against the D2 DA-class receptors in the striatum.

Modulation of spinal excitability by a sub-threshold stimulation of M1 area during muscle lengthening

It is well known that the H-reflex amplitude decreases during passive muscle lengthening in comparison with passive shortening. However, this decrease in spinal synaptic efficacy observed during passive lengthening seems to be lesser during eccentric voluntary contraction. The aim of the present study was to examine whether spinal excitability during lengthening condition could be modulated by magnetic brain stimulation. H reflexes of the triceps surae muscles were elicited on 10 young healthy subjects, and conditioned by a sub-threshold transcranial magnetic stimulation (TMS). The conditioning stimulation was applied over the M1 area of triceps surae muscles at an intensity below motor threshold with a conditioning-test interval of 5ms. Conditioned and non-conditioned H-reflexes were elicited at rest, during passive lengthening and shortening, and during submaximal contractions (concentric, eccentric and isometric). During passive and active lengthening, H reflexes conditioned by a sub-threshold TMS pulse increased on average by 50% compared with non-conditioned responses. No significant effect was found during isometric and concentric conditions. Activation of the corticospinal pathway would partially cancel inhibitions caused by muscle stretch, and according to the time-delayed effect, this result suggested the existence of a specific polysynaptic pathway. In additional experiments, H responses were conditioned by cervico-medullary stimulations, showing that the modulation described by the previous results involves subcortical mechanisms. This study provides further evidences that the modulation of the final cortico-spinal command reaching the muscle depends on a central mechanism that controls peripheral input, such as Ia afference discharge during lengthening.