Riluzole reduces hyperactivity of subthalamic neurons induced by unilateral 6-OHDA lesion in the rat brain.

An abnormal increase in the activity of neurons of the subthalamic nucleus is a key pathophysiological feature of Parkinson's disease. We sought to determine whether riluzole, a sodium channel inhibitor that interferes with glutamatergic neurotransmission, affects neuronal activity in this brain region. Intravenous administration of riluzole reduced the discharge rate of subthalamic neurons in rats with 6-OHDA-induced lesions of the midbrain. By contrast, no effect was observed in nonlesioned control animals. This property may contribute to the neuroprotective effects of riluzole in animal models of PD through the modulation of the glutamatergic inputs these neurons feedback to nigral dopaminergic neurons.

Influence of expectation of different rewards on behavior-related neuronal activity in the striatum.

This study investigated how different expected rewards influence behavior-related neuronal activity in the anterior striatum. In a spatial delayed-response task, monkeys reached for a left or right target and obtained a small quantity of one of two juices (apple, grenadine, orange, lemon, black currant, or raspberry). In each trial, an initial instruction picture indicated the behavioral target and predicted the reward. Nonmovement trials served as controls for movement relationships. Consistent preferences in special reward choice trials and differences in anticipatory licks, performance errors, and reaction times indicated that animals differentially expected the rewards predicted by the instructions. About 600 of >2,500 neurons in anterior parts of caudate nucleus, putamen, and ventral striatum showed five forms of task-related activations, comprising responses to instructions, spatial or nonspatial activations during the preparation or execution of the movement, and activations preceding or following the rewards. About one-third of the neurons showed different levels of task-related activity depending on which liquid reward was predicted at trial end. Activations were either higher or lower for rewards that were preferred by the animals as compared with nonpreferred rewards. These data suggest that the expectation of an upcoming liquid reward may influence a fraction of task-related neurons in the anterior striatum. Apparently the information about the expected reward is incorporated into the neuronal activity related to the behavioral reaction leading to the reward. The results of this study are in general agreement with an account of goal-directed behavior according to which the outcome should be represented already at the time at which the behavior toward the outcome is performed.

Effects of intrasubthalamic injection of dopamine receptor agonists on subthalamic neurons in normal and 6-hydroxydopamine-lesioned rats: an electrophysiological and c-Fos study.

Subthalamic neuronal activity is controlled by a dopaminergic innervation, which may act via D1 and D2 dopamine receptors. This study investigates the effect of apomorphine and the selective D1 and D2 agonists, SKF 82958 and quinpirole respectively, in normal and 6-hydroxydopamine-lesioned rats. The effect of microinjection of these drugs into the subthalamic nucleus was assessed by recording unit activity and the expression of the c-Fos-immunoreactive protein in the subthalamic nucleus. Dopaminergic agonists reduced the discharge rate and did not induce c-Fos expression in the normal rat. Apomorphine and quinpirole increased the discharge rate and induced a strong expression of c-Fos-like immunoreactive proteins, whereas SKF 82958 induced a decrease of the discharge rate and a slight expression of c-Fos in 6-hydroxydopamine-lesioned rats. The striking contrast in the changes obtained with apomorphine and quinpirole in normal and 6-hydroxydopamine-lesioned rats is discussed in relation to a hyperexpression of D2 dopaminergic receptors on the GABAergic terminals into the subthalamic nucleus. These results show that, in normal rats, dopamine agonists exert an inhibitory control on subthalamic neurons via D1 and D2 receptors. However, in 6-hydroxydopamine-lesioned rats, the hyperactivity of subthalamic neurons is also reduced by D1 receptor agonist but not by D2 dopamine agonists. This last result points out one aspect of the complex mechanisms underlying the physiopathology of Parkinson's disease.

Electrophysiological and Fos immunohistochemical evidence for the excitatory nature of the parafascicular projection to the globus pallidus.

Extracellular recordings and immunohistological detection of c-Fos-like immunoreactive proteins were used to determine the synaptic effect of the parafascicular projection to the globus pallidus. Electrical stimulation of the parafascicular neurons induced a single-spike excitatory response with a stable latency of 2.3 ms, suggesting a monosynaptically driven effect. Pharmacological stimulation of the parafascicular nucleus with carbachol increased tonically the pallidal discharge rate by 142%. The discharge rate of the pallidal neurons was described by 37% in parafascicular-lesioned rats. These results demonstrate the excitatory nature and the tonic action of the parafasciculopallidal projection. Carbachol activation of parafascicular neurons also induced the synthesis of c-Fos-like immunoreactive proteins in the pallidal neurons. Control experiments in subthalamic-lesioned rats showed that the parafascicular excitation of the pallidal neurons remained, but both electrophysiological and expression of c-Fos-like immunoreactive proteins were attenuated. This suggests that the direct parafascicular excitation of the pallidal neurons is indirectly reinforced by the previously described parafascicular excitatory input to the subthalamic nucleus. Conversely, the effect of this last input to the subthalamic nucleus is dramatically enhanced in rats with pallidal lesion. Our results demonstrate the complex role of the parafascicular nucleus in activating both the globus pallidus and the subthalamic nucleus, two closely related structures. These results illustrate the integrative capacities of the globus pallidus, whose activity is modulated by multiple afferents.

Evidence for a dopaminergic innervation of the subthalamic nucleus in the rat.

The dopaminergic connection from the substantia nigra pars compacta (SNc) and the ventral tegmental area (VTA) to the subthalamic nucleus in the rat was investigated using anterograde and retrograde tracers. Iontophoretic injection of the retrograde tracer fluoro-gold (FG) into the subthalamic nucleus resulted in a substantial number of labeled neurons in the SNc. Immunohistochemistry of tyrosine hydroxylase (TH) confirmed the dopaminergic nature of these labeled neurons. Retrogradely labeled neurons were also found in the VTA. Injection of the anterograde tracer biocytin into the SNc produced biocytin-labeled terminals in the subthalamic nucleus hence providing clear evidence for a dopaminergic innervation of this nucleus. Quantitative analysis of labeled axons revealed that there were 15-38 terminal branches per axon, each branch being 50-150 microm long. The overall dimensions of one terminal arborization were 400 x 250 x 150 microm. There was no clear-cut topographical organization of the projection, but a slight mediolateral difference in the density of terminals. This direct dopaminergic projection is thought to interact with cortical and pallidal inputs in the subthalamic nucleus, which implies that the functions of the subthalamic nucleus are more complex than previously assumed.

Re-evaluation of the functional anatomy of the basal ganglia in normal and Parkinsonian states.

In the late 1980s, a functional and anatomical model of basal ganglia organization was proposed in order to explain the clinical syndrome of Parkinson's disease. According to this model, the pathological overactivity observed in the subthalamic nucleus and the output station of the basal ganglia plays a crucial role in the pathophysiology of the motor signs of Parkinson's disease. The hyperactivity of subthalamic neurons in Parkinsonism is viewed as a direct consequence of a pathological hypoactivity of the external segment of the pallidum. This article reviews recent data from different experimental approaches that challenge the established model of basal ganglia organization by reinterpreting the functional interaction between the external segment of the pallidum and the subthalamic nucleus in both the normal and pathological state. Indeed, recent neurobiochemical studies have rather unexpectedly shown that the GABAergic and metabolic activities of the external pallidum are not decreased in human and non-human primates with Parkinsonism. This absence of any decrease in activity might be explained by the functionally antagonistic influences of the striatal and subthalamic afferences within the external pallidum, as suggested by several anatomical studies. In addition, there are clues from electrophysiological studies to suggest that the hyperactivity found in the subthalamic neurons in Parkinsonism may not depend solely on the level of activity in the external pallidum. In such a framework, the hyperactivity of the subthalamic neurons would have to be explained, at least in part, by other sources of excitation or disinhibition. However, any explanation for the origin of the subthalamic overactivity in Parkinsonism remains speculative.

Increased subthalamic neuronal activity after nigral dopaminergic lesion independent of disinhibition via the globus pallidus.

Electrophysiological records of unit activity were used to compare the effects of excitotoxic pallidal lesions and 6-hydroxydopamine-induced damage to the midbrain dopaminergic neurons on the discharge rates and patterns of the subthalamic neurons. Removal of the pallidal input induced a slight, but statistically significant, increase (19.5%) in the discharge rate and no change in the firing pattern when compared to control animals. The rats with a dopaminergic lesion showed greater increase (105.7%) while the firing pattern activity of the subthalamic neurons became more irregular, with burst. These results indicate that the increased activity of the subthalamic neurons following a midbrain dopaminergic lesion cannot be due solely to inhibition-disinhibition involving the striato-pallido-subthalamic pathway and induced by the striatal dopaminergic depletion.

Electrophysiological study of the excitatory parafascicular projection to the subthalamic nucleus and evidence for ipsi- and contralateral controls.

The activity of subthalamic neurons was recorded extracellularly in anaesthetized rats after stimulation, inhibition or lesioning of the parafascicular nucleus. Electrical stimulation of the parafascicular nucleus evoked a complex response with two excitatory phases. The first response was correlated with a monosynaptically-driven excitation via a parafascicular input to the subthalamic nucleus. Since the second phase was observed even when the early excitation was not recorded and was eliminated by lesion of the globus pallidus, we suggest that it is not generated by a mechanism intrinsic to the subthalamic nucleus and is due to a disinhibitory effect originating from the globus pallidus. Microinjection of carbachol into the parafascicular nucleus enhanced by 119% the discharge rate of the neurons in the ipsilateral subthalamic nucleus and that of muscimol decreased the discharge rate by 91%. Opposite changes, a decrease of the discharge rate of 49% after microinjection of carbachol and an increase of 47% after muscimol, occurred in the contralateral subthalamic nucleus. In contrast to the above results, the unilateral excitotoxic lesion of the parafascicular nucleus, performed one week before recording, decreased the discharge rate by 69% of the ipsilateral subthalamic nucleus neurons and by 34% that of the contralateral neurons. We suggest that the parafascicular input to the subthalamic nucleus is an excitatory pathway which can tonically drive the neuronal activity in this structure. The opposite changes recorded in the ipsi- and contralateral subthalamic nucleus during unilateral microinjection of excitatory or inhibitory drugs in the parafascicular nucleus emphasize the importance of this thalamic structure in the bilateral regulation of basal ganglia activity via the subthalamic nucleus.