Cortical areas involved in behavioral expression of external pallidum dysfunctions: A PET imaging study in non-human primates.

The external pallidum (GPe) is a component of the indirect pathway centrally placed in the basal ganglia. Studies already demonstrated that the pharmacological disinhibition of the sensorimotor, associative, and limbic GPe produced dyskinesia, hyperactivity, and compulsive behaviors, respectively. The aim of this study was to investigate the cortical regions altered by the disinhibition of each GPe functional territory. Thus, 5 macaques were injected with bicuculline in sensorimotor, associative, and limbic sites of the GPe producing dyskinesia, hyperactivity, and compulsive behaviors, and underwent in vivo positron tomography with 18F-2-fluoro-2-deoxy-D-glucose to identify cortical dysfunctions related to GPe disinhibition. Blood cortisol levels were also quantified as a biomarker of anxiety for each condition. Our results showed that pallidal bicuculline injections in anesthetized animals reproducibly modified the activity of specific ipsilateral and contralateral cortical areas depending on the pallidal territory targeted. Bicuculline injections in the limbic GPe led to increased ipsilateral activations in limbic cortical regions (anterior insula, amygdala, and hippocampus). Injections in the associative vs. sensorimotor GPe increased the activity in the ipsilateral midcingulate vs. somatosensory and parietal cortices. Moreover, bicuculline injections increased blood cortisol levels only in animals injected in their limbic GPe. These are the first functional results supporting the model of opened cortico-striato-thalamo-cortical loops where modifications in a functional pallidal territory can impact cortical activities of the same functional territory but also cortical activities of other functional territories. This highlights the importance of the GPe as a crucial node in the top-down control of the cortico-striato-thalamo-cortical circuits from the frontal cortex to influence the perception, attention, and emotional processes at downstream (or non-frontal) cortical levels. Finally, we showed the implication of the ventral pallidum with the amygdala and the insular cortex in a circuit related to aversive processing that should be crucial for the production of anxious disorders.

Cortico-basal ganglia circuits involved in different motivation disorders in non-human primates.

The ventral striatum (VS) is of particular interest in the study of neuropsychiatric disorders. In this study, performed on non-human primates, we associated local perturbation with monosynaptic axonal tracer injection into medial, central and lateral VS to characterize anatomo-functional circuits underlying the respective expression of sexual manifestations, stereotyped behaviors and hypoactive state associated with loss of food motivation. For the three behavioral effects, we demonstrated the existence of three distinct cortico-basal ganglia (BG) circuits that were topographically organized and overlapping at some cortical (orbitofrontal cortex, anterior cingulate cortex) and subcortical (caudal levels of BG) levels, suggesting interactions between motivation domains. Briefly, erection was associated with a circuit involving the orbitofrontal cortex, medial prefrontal cortex (areas 10, 11) and limbic parts of BG, i.e. medial parts of the pallidal complex and the substantia nigra pars reticulata (SNr). Stereotyped behavior was linked to a circuit involving the lateral orbitofrontal cortex (area 12/47) and limbic parts of the pallidal complex and of the SNr, while the apathetic state was underlined by a circuit involving not only the orbital and medial prefrontal cortex but also the lateral prefrontal cortex (area 8, 45), the anterior insula and the lateral parts of the medial pallidal complex and of the ventro-medial SNr. For the three behavioral effects, the cortico-BG circuits mainly involved limbic regions of the external and internal pallidum, as well as the limbic part of the substantia nigra pars reticulata (SNr), suggesting the involvement of both direct and indirect striatal pathways and both output BG structures. As these motivation disorders could still be induced in dopamine (DA)-depleted monkeys, we suggest that DA issued from the substantia nigra pars compacta (SNc) modulates their expression rather than causes them. Finally, this study may give some insights into the structure to target to achieve therapeutic benefits from deep brain stimulation in motivation disorders.

Selective dysfunction of basal ganglia subterritories: From movement to behavioral disorders.

Historically, Parkinson's disease (PD) was defined as a pure movement disorder. Currently, it is widely accepted that this disease is also characterized by nonmotor signs, such as depression, apathy, and anxiety. On the other hand, the consideration of Gilles de la Tourette syndrome (GTS) as a neuropsychiatric disorder has also been debated. In this review, we will focus on these two disorders, which combine both motor and behavioral features and in which dysfunction of cortical and subcortical regions was suggested. Anatomical, experimental, and clinical data are reported to support the involvement of basal ganglia (BG) in cognitive and motivational functions in addition to motor control. In PD, the nonmotor signs could result from the heterogeneity of dopaminergic lesions and excessive activation of the dopamine receptors, particularly within the limbic neuronal networks. Experimental results obtained on nonhuman primates using local disinhibition within functional territories of BG allowed the precise mapping of their motor and nonmotor functions. Thus, impairment of inhibitory control inside specific striatal territories induced behavioral disorders and abnormal movements, which had striking similarities to clinical expressions of GTS. Establishing such a relationship between BG subterritories and motor and behavioral disorders could potentially be helpful for future target choices for DBS in many neuropsychiatric disorders. Furthermore, it is also of great interest for therapeutic research and for the efficient targeting of symptom relief to determine the precise pharmacological effects of the two main modulators of BG function, which are dopamine and serotonin.

Towards a primate model of Gilles de la Tourette syndrome: anatomo-behavioural correlation of disorders induced by striatal dysfunction.

INTRODUCTION: Gilles de la Tourette syndrome (GTS) is characterized by abnormal movements (tics) often associated with behavioural disorders. Neuropathological data from GTS patients have suggested that aberrant activation of distinct striatal functional territories could produce a large spectrum of GTS symptoms. In a monkey model, injections of GABA-antagonist into the striatum enabled us to produce tic-like movements, hyperactivity and stereotyped behaviours. These effects had similarities with simple motor tics, hyperactivity and compulsive behaviours observed in GTS patients. In this study, we first aimed to identify the neuronal circuits involved in the different behavioural effects using anatomical antero/retrograde tracer in monkeys. We also compared the neuronal circuits thus obtained with the available neuro-anatomical data on GTS patients. METHODS: Using injections of axonal tracer into different functional parts of the striatum of eight monkeys, we identified cortical, thalamic and basal ganglia regions related to the expression of tic-like movements, hyperactivity and stereotyped behaviours induced in response to microinjection of GABA-antagonist. RESULTS: In this monkey model, different anatomical circuits involving distinct cortical and thalamic areas and sub-territories of the basal ganglia underpinned movement and behavioural disorders. Thus, tic-like movements were associated with neuronal labelling within the sensorimotor network, mostly in the medial and lateral premotor cortex and sensorimotor parts of the basal ganglia. Neuronal labelling in the prefrontal dorso-lateral cortex and associative territories of the basal ganglia was related to hyperactivity disorder and stereotyped behaviours were linked to the orbitofrontal cortex and limbic part of the basal ganglia. CONCLUSIONS: These results support the hypothesis that different behavioural effects could arise from distinct but inter-digitated neuronal circuits. As these behavioural disorders shared some similarities with simple motor tics, hyperactivity and compulsive behaviours observed in GTS patients, this model could be a good tool for future studies involving the modulation of neuronal circuits, such as deep brain stimulation.

Effects of dopamine and serotonin antagonist injections into the striatopallidal complex of asymptomatic MPTP-treated monkeys.

The cardinal symptoms of Parkinson's disease (PD), akinesia, rigidity and tremor, are only observed when the striatal level of dopamine (DA) is decreased by 60-80%. It is likely that compensatory mechanisms during the early phase of DA depletion delay the appearance of motor symptoms. In a previous study, we proposed a new PD monkey model with progressive MPTP intoxication. Monkeys developed all of the motor symptoms and then fully recovered despite a large DA cell loss in the substantia nigra (SN). Compensatory mechanisms certainly help to offset the dysfunction induced by the DA lesion, facilitating motor recovery in this model. Neurotransmitter measurements in the striatal sensorimotor and associative/limbic territories of these monkeys subsequently revealed that DA and serotonin (5-HT) could play a role in recovery mechanisms. To try to determine the involvement of these neurotransmitters in compensatory mechanisms, we performed local injections of DA and 5-HT antagonists (cis-flupenthixol and mianserin, respectively) into these two striatal territories and into the external segment of the globus pallidus (GPe). Injections were performed on monkeys that were in an asymptomatic state after motor recovery. Most parkinsonian motor symptoms reappeared in animals with DA antagonist injections either in sensorimotor, associative/limbic striatal territories or in the GPe. In contrast to the effects with DA antagonist, there were mild parkinsonian effects with 5-HT antagonist, especially after injections in sensorimotor territories of the striatum and the GPe. These results support a possible, but slight, involvement of 5-HT in compensatory mechanisms and highlight the possible participation of 5-HT in some behavioural disorders. Furthermore, these results support the notion that the residual DA in the different striatal territories and the GPe could be involved in important mechanisms of compensation in PD.

Discontinuous long-train stimulation in the anterior striatum in monkeys induces abnormal behavioral states.

The striatum has been identified as a new target for therapeutic deep brain stimulation in the treatment of neurological and psychiatric disorders. The nonhuman primate model offers opportunities for detailed mapping of the behavioral effects of stimulation within the striatum. We recently showed that dysfunction in the dorsal and ventral striatum was able to produce a specific pattern of abnormal movements and behavioral states. In the present study, electrical stimulation of monkey striatum evoked abnormal movements and behavioral states depending not only on the location of stimulation sites but also on the parameters of stimulation. Abnormal movements were induced by stimulation of sites in the anterior associative and posterior sensorimotor striatum. Short-train stimulation evoked myoclonic-like movements and long-train stimulation produced sustained dystonic-like and complex abnormal movements. Long-train stimulation of the anterior part of the striatum, corresponding to the associative-limbic territory, induced 3 abnormal behavioral states--hyperactivity, hypoactivity, and stereotyped behaviors. Short-train stimulation was less effective in producing these effects. No significant effects were observed with the continuous mode of stimulation. Our results show that discontinuous long-train stimulation of the anterior associative and limbic parts of the striatum is the most effective mode of stimulation to produce these behavioral states.

Behavioral and movement disorders induced by local inhibitory dysfunction in primate striatum.

The current model of basal ganglia organization postulates their functional division into sensorimotor, associative, and limbic territories, implicated, respectively, in motor, cognitive, and motivational aspects of behavior. Based on this model, we previously demonstrated, in the external segment of globus pallidus of monkeys, that the same neuronal dysfunction induced dyskinesia or abnormal behavior depending on the functional territory. To extend these findings, we performed bicuculline microinjections into the different functional territories of the striatum in 6 monkeys. Abnormal movements were observed after microinjections into the posterior putamen, corresponding to the sensorimotor territory, and into the dorsal part of the anterior striatum, corresponding to the associative functional territory. Within the ventral striatum, referred to as the limbic functional territory, we identified 3 subregions corresponding to different types of abnormal behaviors. Simultaneous neuronal recordings performed close to the microinjection sites confirmed that bicuculline produced a focal increase of neuronal activity surrounded by a zone with neuronal hypoactivity. This study provides new evidence for the involvement of specific striatal regions in movement as well as in a large spectrum of behavioral disorders and suggests that local inhibitory dysfunction could be a pathological mechanism of various neurological and psychiatric disorders.

Behavioral recovery in MPTP-treated monkeys: neurochemical mechanisms studied by intrastriatal microdialysis.

Parkinson's disease (PD) patients express motor symptoms only after 60-80% striatal dopamine (DA) depletion. The presymptomatic phase of the disease may be sustained by biochemical modifications within the striatum. We used an appropriate specific 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP) monkey model (Mounayar et al., 2007) to study the compensatory mechanisms operating in recovery from PD motor symptoms. We assessed the levels of DA and its metabolites (DOPAC, homovanillic acid), GABA, glutamate (Glu), serotonin (5-HT) and its metabolite (5HIAA) by repeated intracerebral microdialysis in awake animals before exposure to MPTP during full expression of the motor symptoms induced by MPTP and after recovery from these symptoms. Measurements were obtained from two functionally and anatomically different striatal areas: the associative-limbic territory and sensorimotor territory. Animals with motor symptoms displayed an extremely large decrease in levels of DA and its metabolites and an increase in Glu and GABA levels, as reported by other studies. However, we show here for the first time that serotonin levels increased in these animals. We found that increases in DA levels in the sensorimotor and/or associative-limbic territory and high levels of 5-HT and of its metabolite, 5HIAA, were associated with recovery from motor symptoms in this model. Determining whether similar changes in DA and 5-HT levels are involved in the compensatory mechanisms delaying the appearance of motor symptoms in the early stages of PD might make it possible to develop new treatment strategies for the disease.

High-frequency stimulation of the anterior subthalamic nucleus reduces stereotyped behaviors in primates.

Growing evidence shows that dysfunction of the limbic basal ganglia (BG) network is implicated in repetitive behaviors, such as obsessive compulsive disorder (OCD) and Tourette's syndrome (TS), in humans. Because deep brain stimulation (DBS) of the posterior subthalamic nucleus (STN), which modulates the sensorimotor BG network, is beneficial in movement disorders, stimulation of the anterior, limbic STN might improve intractable behavioral disorders. We therefore evaluated the effect of anterior STN stimulation on the repetitive behaviors induced in two monkeys after bicuculline-induced dysfunction of the limbic external globus pallidus. DBS in the anterior STN dramatically reduced the stereotypies, but had no effect on the performance of a simple food retrieval task. Stimulations outside the STN were less effective in reducing the stereotypies. Electrode trajectories, reconstructed postmortem, confirmed that the effective contacts were in the anterior STN. DBS in the limbic STN might therefore provide relief from the severe stereotyped behaviors observed in OCD and TS.

A new model to study compensatory mechanisms in MPTP-treated monkeys exhibiting recovery.

The cardinal symptoms in Parkinson's disease (PD), akinesia, rigidity and tremor, are only observed when the striatal level of dopamine is decreased by 60-80%. During the preclinical phase of PD, compensatory mechanisms are probably involved in delaying the appearance of motor symptoms. In a MPTP (1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine) monkey model of PD, a spontaneous recovery has been reported after initial intoxication suggesting that compensatory mechanisms are activated in this model as well. Assuming that mechanisms are similar in these phenomena, the study of recovery in monkeys following MPTP intoxication may enable identification of compensatory mechanisms involved in the preclinical phase of PD. In order to maximize the temporal similarity between PD and the MPTP model, we assessed a new progressive monkey model in which spontaneous recovery is expressed systematically and to characterize it based on (1) its behavioural features, and (2) the presence of compensatory mechanisms revealed by an immunohistological approach comparing dopaminergic and serotoninergic innervation between monkeys either exhibiting behavioural recovery or stable motor symptoms. This immunohistological study focused on the substantia nigra, striatum and pallidum, and their anatomical and functional subdivisions: sensorimotor, associative and limbic. The behavioural analysis revealed that with progressive MPTP intoxication motor symptoms were initially expressed in all monkeys. Observable recovery from these symptoms occurred in all monkeys (7/7) within 3-5 weeks after the last MPTP injection, and most exhibited a full recovery. In contrast, acute intoxication induced stable motor symptoms. Despite this obvious behavioural difference, immunohistological methods revealed that the loss of dopaminergic cell bodies in substantia nigra was substantial and similar in both MPTP-treated groups. However, quantification of fibres revealed that recovered monkeys displayed more dopaminergic and serotoninergic fibres than those with stable motor symptoms in sensorimotor and associative territories of striatum and more dopaminergic fibres in internal pallidum. This study provides a new model of PD where all monkeys expressed functional recovery from motor symptoms despite a large dopaminergic neuronal loss. The immunohistological results suggest that both dopamine and serotonin could be implicated in the compensatory mechanisms.

Parafascicular nucleus projection to the extrastriatal basal ganglia in monkeys.

We have analyzed the parafascicular thalamic projection to extrastriatal structures of the basal ganglia using anterograde and retrograde tracing in monkeys. We identified (1) retrogradely labeled neurons in the parafascicular nucleus projecting to the anteromedial, limbic part of the external and internal pallidum, the substantia nigra and the subthalamic nucleus, (2) labeled terminals scattered in all these structures after anterograde tracer injection into the medial part of the parafascicular nucleus and (3) individual parafascicular terminals that arborized rather poorly in a large portion of each basal ganglia structure. Our study provides evidence that the parafascicular nucleus, and especially its medial part, can relay emotional and motivational information back to all basal ganglia components in primates.

The mitochondrial complex I inhibitor rotenone triggers a cerebral tauopathy.

Reduced activity of the mitochondrial respiratory chain--particularly complex I--may be implicated in the etiology of both Parkinson's disease and progressive supranuclear palsy, although these neurodegenerative diseases differ substantially as to their distinctive pattern of neuronal cell loss and the predominance of cerebral alpha-synuclein or tau protein pathology. To determine experimentally whether chronic generalized complex I inhibition has an effect on the distribution of alpha-synuclein or tau, we infused rats systemically with the plant-derived isoflavonoid rotenone. Rotenone-treated rats with a pronounced metabolic impairment had reduced locomotor activity, dystonic limb posture and postural instability. They lost neurons in the substantia nigra and in the striatum. Spherical deposits of alpha-synuclein were observed in a few cells, but cells with abnormal cytoplasmic accumulations of tau immunoreactivity were significantly more numerous in the striatum of severely lesioned rats. Abnormally high levels of tau immunoreactivity were found in the cytoplasm of neurons, oligodendrocytes and astrocytes. Ultrastructurally, tau-immunoreactive material consisted of straight 15-nm filaments decorated by antibodies against phosphorylated tau. Many tau+ cell bodies also stained positive for thioflavin S, nitrotyrosine and ubiquitin. Some cells with abnormal tau immunoreactivity contained activated caspase 3. Our data suggest that chronic respiratory chain dysfunction might trigger a form of neurodegeneration in which accumulation of hyperphosphorylated tau protein predominates over deposits of alpha-synuclein.

The cerebellum communicates with the basal ganglia.

The cerebral cortex is interconnected with two major subcortical structures: the basal ganglia and the cerebellum. How and where cerebellar circuits interact with basal ganglia circuits has been a longstanding question. Using transneuronal transport of rabies virus in macaques, we found that a disynaptic pathway links an output stage of cerebellar processing, the dentate nucleus, with an input stage of basal ganglia processing, the striatum.

Thalamic neuronal activity in dopamine-depleted primates: evidence for a loss of functional segregation within basal ganglia circuits.

Different analyses of neuronal activity in primate models of Parkinson's disease (PD) have resulted in two different views on the effects of dopamine depletion. The first is based on the higher firing rate and bursty firing pattern, and assumes that dopamine depletion results in a hyperactivity of basal ganglia (BG) output structures. The second is based on the less-specific responses to passive joint manipulation and the excessive correlations between neuronal discharges, and assumes that dopamine depletion results in a loss of functional segregation in cortico-BG circuits. The aim of the present study was to test out the predictions of these two different views on thalamic neuronal activity. Three male vervet monkeys (Cercopithecus aethiops) were progressively intoxicated with 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP). Neuronal activities were characterized using standard analyses (firing rates and patterns, receptive fields, and cross-correlations) and compared between the normal, asymptomatic (before the stabilization of motor symptoms), and parkinsonian (with persistent akinesia and rigidity) stages of MPTP intoxication. The pallidonigral thalamus (receiving projections from the BG) was characterized in both the asymptomatic and parkinsonian states by (1) an unchanged firing rate and pattern and (2) a proliferation of nonspecific neurons and correlated pairs. In contrast, the cerebellar thalamus (receiving projections from the cerebellum), was characterized by no change (asymptomatic state) or minor changes (symptomatic state). Thus the major dysfunction after dopamine depletion appeared to be the loss of functional segregation within cortico-BG circuits, which could also be at the heart of parkinsonian pathophysiology.

Persistent increase in olfactory type G-protein alpha subunit levels may underlie D1 receptor functional hypersensitivity in Parkinson disease.

Although L-dopa remains the most effective treatment of Parkinson disease, its long-term administration is hampered by the appearance of dyskinesia. Hypersensitivity of dopamine D1 receptors in the striatum has been suggested to contribute to the genesis of these delayed adverse effects. However, D1 receptor amounts are unchanged in Parkinson disease, suggesting alterations of downstream effectors. In rodents, striatal D1 receptors activate adenylyl cyclase through olfactory type G-protein alpha subunit (Galphaolf) and G-protein gamma 7 subunit (Ggamma7). We found that Galphaolf was enriched in human basal ganglia and was markedly diminished in the putamen of patients with Huntington disease, in relation with the degeneration of medium spiny neurons. In contrast, in the putamen of patients with Parkinson disease, Galphaolf and Ggamma7 levels were both significantly increased. In the rat, the degeneration of dopamine neurons augmented Galphaolf levels in the striatal neurons, specifically at the plasma membrane, an effect accounting for the increase of D1 response on cAMP production in dopamine-depleted striatum. In lesioned rats, Galphaolf levels were normalized by a 3 week treatment with l-dopa or a D1 agonist but not with aD2-D3 agonist, supporting a Galphaolf regulation by D1 receptor usage. In contrast, the increases of Galphaolf levels in patients were not affected by the duration of l-dopa treatment but correlated with duration of disease. In conclusion, our results revealed in the parkinsonian putamen a prolonged elevation of Galphaolf levels that may lead to a persistent D1 receptor hypersensitivity and contribute to the genesis of long-term complications of L-dopa.

Behavioural disorders induced by external globus pallidus dysfunction in primates II. Anatomical study.

The anatomical organization of the basal ganglia supports their involvement in movement and behavioural disorders. Thus dyskinesia, attention deficit with or without hyperactivity, and stereotyped behaviour can be induced by microinjections of bicuculline, a GABAergic antagonist, into different parts of the external globus pallidus (GPe) in monkeys. The aim of the present study was to determine the anatomo-functional circuits inside the basal ganglia which are specifically related to each of these behavioural changes. For that, axonal tracers were injected in the same pallidal sites where abnormal behaviours have previously been obtained by bicuculline microinjections. The labelling was mapped in the different basal ganglia and matched with the topography of the cortico-striato-pallidal projections already reported in the literature and with the distribution of calbindin immunoreactivity. Our results first show that the pallidal sites related to dyskinesia, attention deficit with or without hyperactivity, and stereotyped behaviour, were respectively in motor, associative and limbic territories, defined as weak, moderate and intensive calbindin immunoreactivity. The same relationship was observed between the distribution of the labelling in the different basal ganglia after tracer injections performed in these different pallidal sites and the anatomo-functional territories. Thus regarding the origin of the circuits within the striatum, tracer injections performed in the dyskinesia site labelled neurons located in the posterior sensorimotor putamen, those performed in the hyperactivity and/or attention deficit labelled neurons in the laterodorsal putamen and caudate nucleus, regions corresponding to associative and anterior motor territories, while those performed in the stereotyped behaviour site labelled neurons in the ventral limbic striatum. Regarding the GPe output on the basal ganglia, the different circuits also appeared underlined by different anatomo-functional territories, even if a partial overlap exists. Each of these anatomical circuits systematically involves both the internal globus pallidus (GPi) and the substantia nigra pars reticulata (SNr) but, whereas movement circuit is mainly related to the GPi, stereotyped behaviour is mainly related to the SNr. Additionally, subregions of the subthalamic nucleus were also systematically involved, depending on the movement or behavioural disorder produced. These results demonstrate that distinct circuits involving different anatomo-functional territories of the basal ganglia, with partial overlap, participate in different behavioural disorders in monkeys. It seems likely that these neuronal circuits are involved in pathologies like Tourette's syndrome, attention deficit/hyperactivity disorders and obsessional compulsive troubles. This study provides the basis for further researches with a therapeutical viewpoint.

Behavioural disorders induced by external globus pallidus dysfunction in primates: I. Behavioural study.

The current model of basal ganglia organization postulates the existence of a functional partitioning into sensorimotor, associative and limbic territories, implicated in motor, cognitive and emotional aspects of behaviour, respectively. This organization was proposed initially on the basis of the cortico-striatal projections and was extended to the various structures of the basal ganglia. While there is a considerable body of experimental evidence in support of an involvement of the basal ganglia sensorimotor territory in basic control of movements, evidence for the functional relevance of the non-motor territories has had to be based on a growing number of clinical observations due to the paucity of relevant animal studies. Previous studies in monkeys have, however, shown that a reversible and focal dysfunction induced by microinjections of bicuculline in the sensorimotor territory of the external globus pallidus (GPe) can generate abnormal movements. We therefore hypothesized that the same approach applied to the associative and limbic territories of the GPe would induce behavioural disorders rather than abnormal movements. To address this hypothesis, we performed microinjections of bicuculline, using the same concentration in each of the sensorimotor, associative and limbic territories of the GPe, as defined by striato-pallidal projections. Spontaneous behaviour and performance of a simple food-retrieving task during the effects of these microinjections were compared with data obtained in control conditions in the same monkeys. We found that bicuculline microinjections induced stereotypy when performed in the limbic part of the GPe, and attention deficit and/or hyperactivity when performed in the associative part. No movement disorders were observed during these behavioural disturbances. As previously described, abnormal movements were observed when bicuculline was injected into the sensorimotor territory of the GPe. The relationship between the localization of microinjection sites and the type of behavioural effect was similar for the three monkeys. Control microinjections of bicuculline into surrounding structures (striatum and internal globus pallidus) and saline injections into the GPe failed to induce any observable effect. These results support the hypotheses of functional diversity and territorial specificity in the GPe, in agreement with the parallel circuits organizational model of the basal ganglia. Furthermore, the behavioural effects shared similar features with symptoms observed in Tourette's syndrome, attention deficit/hyperactivity and compulsive disorders. Thus, our study provides experimental evidence for the involvement of the associative and limbic parts of the basal ganglia in these pathologies. These results may provide the basis for a primate model of these disorders.

Disruption of self-organized actions in monkeys with progressive MPTP-induced parkinsonism. I. Effects of task complexity.

Parkinson's disease (PD) is characterized by motor symptoms, usually accompanied by cognitive deficits. The question addressed in this study is whether complexity of routine actions can exacerbate parkinsonian disorders that are often considered to be motor symptoms. To examine this question, we trained four vervet monkeys (Cercopithecus aethiops) to perform three multiple-choice retrieval tasks. In order of ascending complexity, rewards were freely available (task 1), covered with transparent sliding plaques (task 2), and covered with opaque sliding plaques cued by symbols (task 3). Thus, from task 1 to task 2 we added a motor difficulty--the recall of context-adapted movement; and from task 2 to task 3 we added a cognitive difficulty: the recall of symbol-reward associations. The more complex the task, the longer it took to learn, but after extensive training the performance was stable in all tasks, with similar retrieval durations. The monkeys then received systemic 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP) injections (0.3-0.4 mg/kg) every 4-7 days, until the first motor symptoms appeared. In the course of MPTP intoxication, the behavioural performance declined while the motor symptoms were absent or mild--the retrieval duration increased, and non-initiated choices and hesitations between choices became frequent. Interestingly, this decline was in proportion to task complexity, and was particularly pronounced with the cognitive difficulty. Furthermore, freezing appeared only with the cognitive difficulty. We therefore suggest that everyday cognitive difficulties may exacerbate hypokinesia (lack of initiation, abnormal slowness) and executive disorders (hesitations, freezing) in the early stages of human PD.

Disruption of self-organized actions in monkeys with progressive MPTP-induced parkinsonism: II. Effects of reward preference.

The motor and cognitive symptoms of Parkinson's disease (PD) are well documented, but little is known about the functionality of motivational processes mediated by the limbic circuits of basal ganglia. The aim of this study was to test the ability of motivational processes to direct and to urge behaviour, in four vervet monkeys (Cercopithecus aethiops) progressively intoxicated with systemic 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP) injections (0.3-0.4 mg/kg every 4-7 days). In the food preference task, the monkeys had to retrieve two types of directly visible food, simultaneously available in the wells of a reward board. At all stages of MPTP-induced parkinsonism, the monkeys continued to take their favourite food first. In the symbol discrimination task, the wells were covered with sliding plaques cued by symbols indicating the absence or presence of a reward, and the different types of food were blocked in separate sessions. Monkeys with mild or moderate parkinsonism made fewer attempts and took longer to retrieve non-preferred compared with preferred rewards. These results indicate that motivational processes are still able to direct (food preference task) and to urge (symbol discrimination task) behaviour in MPTP-lesioned monkeys. Such a functional preservation may be related to the relatively spared dopaminergic innervation of the limbic circuits that we found in our monkeys, in agreement with the literature on humans. Furthermore, the frequency of executive disorders (such as hesitations and freezing) appeared to be much lower with the preferred rewards. Thus, the preserved motivational processes may help to overcome executive dysfunction in the early stages of human PD.