Long term modification of cerebellar inhibition after inferior olive degeneration

Elimination of the error signal in the superior colliculus impairs saccade motor learning

Theories of cerebellar-dependent motor learning use the error between the desired and actual movement to correct the erroneous movement. To support this idea, several studies have tried to eliminate the error signal to the cerebellum and demonstrate an impairment of learning. However, such former approaches have not been successful because blocking the error signal also affected the movement to be learned. In this study, we selectively block an error signal for saccade adaptation, a type of cerebellar motor learning, by inactivating the source of the error signal in the superior colliculus without affecting the movement to be learned. Saccade adaptation was impaired. Thus, our study provides the first experimental evidence that an error signal is required for cerebellar motor learning.

When movements become dysmetric, the resultant motor error induces a plastic change in the cerebellum to correct the movement, i.e., motor adaptation. Current evidence suggests that the error signal to the cerebellum is delivered by complex spikes originating in the inferior olive (IO). To prove a causal link between the IO error signal and motor adaptation, several studies blocked the IO, which, unfortunately, affected not only the adaptation but also the movement itself. We avoided this confound by inactivating the source of an error signal to the IO. Several studies implicate the superior colliculus (SC) as the source of the error signal to the IO for saccade adaptation. When we inactivated the SC, the metrics of the saccade to be adapted were unchanged, but saccade adaptation was impaired. Thus, an intact rostral SC is necessary for saccade adaptation. Our data provide experimental evidence for the cerebellar learning theory that requires an error signal to drive motor adaptation.

Blocking glutamate-mediated inferior olivary signals abolishes expression of conditioned eyeblinks but does not prevent their acquisition

The inferior olive (IO) is considered a crucial component of the eyeblink conditioning network. The cerebellar learning hypothesis proposes that the IO provides the cerebellum with a teaching signal that is required for the acquisition and maintenance of conditioned eyeblinks. Supporting this concept, previous experiments showed that lesions or inactivation of the IO blocked CR acquisition. However, these studies were not conclusive. The drawback of the methods used by those studies is that they not only blocked task-related signals, but also completely shut down the spontaneous activity within the IO, which affects the rest of the eyeblink circuits in a nonspecific manner. We hypothesized that more selective blocking of task-related IO signals could be achieved by using injections of glutamate antagonists, which reduce, but do not eliminate, the spontaneous activity in the IO. We expected that if glutamate-mediated IO signals are required for learning, then blocking these signals during training sessions should prevent conditioned response (CR) acquisition. To test this prediction, rabbits were trained to acquire conditioned eyeblinks to a mild vibrissal airpuff as the conditioned stimulus while injections of the glutamate antagonist γ-d-glutamylglycine were administered to the IO. Remarkably, even though this treatment suppressed CRs during training sessions, the postacquisition retention test revealed that CR acquisition had not been abolished. The ability to acquire CRs with IO unconditioned stimulus signals that were blocked or severely suppressed suggests that mechanisms responsible for CR acquisition are extremely resilient and probably less dependent on IO-task-related signals than previously thought.

Progressive limb ataxia following inferior olive lesions

Cerebellar climbing fibres originate in the inferior olive (IO). Temporary IO inactivation produces movement deficits. Does permanent inactivation produce similar deficits and, if so, do they recover? The excitotoxin, kainic acid, was injected into the rostral IO of three cats. Behaviour was measured during reaching and locomotion. Two cats were injected during the reaching task. Within minutes, grasping became difficult and the trajectories of the reaches showed higher arcing than normally seen. During locomotion, both cats showed head and trunk deviation to the injected side, walking paths curved to the injected side, and the paws were lifted higher than normal. Limbs contralateral to the injections became rigid. Within 1 day, posture had normalized, locomotion was unsteady and high lifting of the paws had reversed to a tendency to drag the dorsum of the paws. Passive body movement produced vestibular signs. Over a few days, locomotion normalized and vestibular signs disappeared. Reach trajectories were normal but grasping deficits persisted. Over the first week, the amplitude of limb lift during reaching and locomotion began to increase. The increase continued over time and, after several months, limb movements became severely ataxic. The effects followed the somatotopy of the rostral IO: a loss of cells in medial rostral IO only affected the forelimb, whereas a loss of cells in medial and lateral IO affected both forelimb and hindlimb. Deficits produced by IO lesions involve multiple mechanisms; some recover rapidly, some appear stable, and some worsen over time. The nature of the progressive deficit suggests a gradual loss of Purkinje cell inhibition on cerebellar nuclear cells.

Control of cerebellar nuclear cells: a direct role for complex spikes?

The question of what modulates the firing of the cerebellar nuclei (CN) is one to which we presently have a surprisingly incomplete answer. Because most synaptic input to the CN originates from Purkinje cells (PCs), and simple spikes (SSs) are far more numerous than complex spikes (CSs), SSs are generally thought to be the dominant influence on the CN. However, evidence, reviewed here, suggests that this appears not to be the case in some physiologically important situations. As an alternative, we propose that CS activity may have at least as significant an effect on CN firing as do SSs. In particular, we suggest that CS activity has a role in controlling the bursts CN neurons show during various movements, during sleep states, and under ketamine-xylazine anesthesia. The ability to perform this role rests on the fact that CSs can be highly synchronized among PCs that project to the same CN neuron. Specifically, we suggest that synchronized CSs help determine the temporal course of the CN bursts, most often their offset, and that SSs and activity from cerebellar afferents may modulate the specific firing pattern within each burst. This joint control of CN activity may help explain anomalies present in the standard model for synaptic control of CN activity in which determination of CN firing patterns is attributed primarily to SSs.

Assessing the role of inferior olivary sensory signaling in the expression of conditioned eyeblinks using a combined glutamate/GABAA receptor antagonist protocol

The inferior olive (IO) is a major component of the eyeblink conditioning neural network. The cerebellar learning hypothesis assumes that the IO supplies the cerebellum with a "teaching" unconditioned stimulus input required for the acquisition of the conditioned response (CR) and predicts that inactivating this input leads to the extinction of CRs. Previous tests of this prediction attempted to block the teaching input by blocking glutamatergic sensory inputs in the IO. These tests were inconclusive because blocking glutamate neurotransmission in the IO produces a nonspecific tonic malfunction of cerebellar circuits. The purpose of the present experiment was to examine whether the behavioral outcomes of blocking glutamate receptors in the IO could be counterbalanced by reducing GABA-mediated inhibition in the IO. We found that injecting the IO with the glutamate antagonist γ-d-glutamylglycine (DGG) abolished previously learned CRs, whereas injecting the GABA(A) receptor antagonist gabazine at the same site did not affect CR incidence but shortened CR latencies and produced tonic eyelid closure. To test whether the glutamate antagonist-induced behavioral deficit could be offset by elevating IO activity with GABA(A) antagonists, rabbits were first injected with DGG and then with gabazine in the same training session. While DGG abolished CRs, follow-up injections of gabazine accelerated their recovery. These findings suggest that the level of IO neuronal activity is critical for the performance of CRs, and that combined pharmacological approaches that maintain spontaneous activity at near normal levels hold tremendous potential for unveiling the role of IO-mediated signals in eyeblink conditioning.

The cerebellum and eye-blink conditioning: learning versus network performance hypotheses

Classical conditioning of the eye-blink reflex in the rabbit is a form of motor learning that is uniquely dependent on the cerebellum. The cerebellar learning hypothesis proposes that plasticity subserving eye-blink conditioning occurs in the cerebellum. The major evidence for this hypothesis originated from studies based on a telecommunications network metaphor of eye-blink circuits. These experiments inactivated parts of cerebellum-related networks during the acquisition and expression of classically conditioned eye blinks in order to determine sites at which the plasticity occurred. However, recent evidence revealed that these manipulations could be explained by a network performance hypothesis which attributes learning deficits to a non-specific tonic dysfunction of eye-blink networks. Since eye-blink conditioning is mediated by a spontaneously active, recurrent neuronal network with strong tonic interactions, differentiating between the cerebellar learning hypothesis and the network performance hypothesis represents a major experimental challenge. A possible solution to this problem is offered by several promising new approaches that minimize the effects of experimental interventions on spontaneous neuronal activity. Results from these studies indicate that plastic changes underlying eye-blink conditioning are distributed across several cerebellar and extra-cerebellar regions. Specific input interactions that induce these plastic changes as well as their cellular mechanisms remain unresolved.

Interaction between Purkinje cells and inhibitory interneurons may create adjustable output waveforms to generate timed cerebellar output

We develop a new model that explains how the cerebellum may generate the timing in classical delay eyeblink conditioning. Recent studies show that both Purkinje cells (PCs) and inhibitory interneurons (INs) have parallel signal processing streams with two time scales: an AMPA receptor-mediated fast process and a metabotropic glutamate receptor (mGluR)-mediated slow process. Moreover, one consistent finding is an increased excitability of PC dendrites (in Larsell's lobule HVI) in animals when they acquire the classical delay eyeblink conditioning naturally, in contrast to in vitro studies, where learning involves long-term depression (LTD). Our model proposes that the delayed response comes from the slow dynamics of mGluR-mediated IP3 activation, and the ensuing calcium concentration change, and not from LTP/LTD. The conditioned stimulus (tone), arriving on the parallel fibers, triggers this slow activation in INs and PC spines. These excitatory (from PC spines) and inhibitory (from INs) signals then interact at the PC dendrites to generate variable waveforms of PC activation. When the unconditioned stimulus (puff), arriving on the climbing fibers, is coupled frequently with this slow activation the waveform is amplified (due to an increased excitability) and leads to a timed pause in the PC population. The disinhibition of deep cerebellar nuclei by this timed pause causes the delayed conditioned response. This suggested PC-IN interaction emphasizes a richer role of the INs in learning and also conforms to the recent evidence that mGluR in the cerebellar cortex may participate in slow motor execution. We show that the suggested mechanism can endow the cerebellar cortex with the versatility to learn almost any temporal pattern, in addition to those that arise in classical conditioning.

Selective impairment of the cerebellar C1 module involved in rat hind limb control reduces step-dependent modulation of cutaneous reflexes

The cerebellum is divided into multiple parasagittally organized modules, which are thought to represent functional entities. How individual modules participate in cerebellar control of complex movements such as locomotion remains largely unknown. To a large extent, this is caused by the inability to study the contribution of individual modules during locomotion. Because of the architecture of modules, based on narrow, elongated cortical strips that may be discontinuous in the rostrocaudal direction, lesion of a complete module, without affecting neighboring modules, has not been possible. Here, we report on a new method for inducing a selective dysfunction of spatially separated parts of a single module using a small cortical injection of a retrogradely transported neurotoxin, cholera toxin b-subunit-saporin. We show that such a local injection into the C1 module results in climbing fiber and partial mossy fiber deafferentation of functionally related areas of this module, thereby resulting in a severe impairment of the whole module without affecting neighboring modules. A subsequent functional analysis indicates that such an impairment of the hindlimb part of the C1 module did not have a significant impact on skilled walking or overall stepping pattern. However, the modulation of cutaneously induced reflexes during stepping was severely diminished. We propose that the C1 module is specifically involved in the adaptive control of reflexes.

Cerebellar dysfunction explains the extinction-like abolition of conditioned eyeblinks after NBQX injections in the inferior olive

Classical conditioning of the eyeblink response is a form of motor learning that is controlled by the intermediate cerebellum and related brainstem structures. The inferior olive (IO) is commonly thought to provide the cerebellum with a "teaching" unconditioned stimulus (US) signal required for cerebellar learning. Testing this concept has been difficult because the IO, in addition to its putative learning function, also controls tonic activity in the cerebellum. Previously, it was reported that inactivation of AMPA/kainate receptors in the IO produces extinction of conditioned responses (CRs), suggesting that it blocks the transmission of US signals without perturbing the functional state of the cerebellum. However, the electrophysiological support for this critical finding was lacking, mostly because of methodological difficulties in maintaining stable recordings from the same set of single units throughout long drug injection sessions in awake rabbits. To address this critical issue, we used our microwire-based multiple single-unit recording method. The IO in trained rabbits was injected with the AMPA/kainate receptor blocker, 1,2,3,4-tetrahydro-6-nitro-2,3-dioxo-benzo[f]quinoxaline-7-sulfonamide (NBQX), and its effects on CR expression and neuronal activity in the cerebellar interposed nuclei (IN) were examined. We found that NBQX abolished CR expression and that delayed drug effects were independent of the presentation of the conditioned stimulus and were therefore not related to extinction. In parallel to these behavioral effects, the spontaneous neuronal activity and CR-related neuronal responses in the IN were suppressed, suggesting cerebellar dysfunction. These findings indicate that testing the role of IO in learning requires methods that do not alter the functional state of the cerebellum.

Developmental neural plasticity and its cognitive benefits: olivocerebellar reinnervation compensates for spatial function in the cerebellum

The adult mammalian central nervous system displays limited reinnervation and recovery from trauma. However, during development, post-lesion plasticity may generate alternative paths, thus providing models to investigate reinnervation and repair. After unilateral transection of the neonatal rat olivocerebellar path (pedunculotomy), axons from the remaining inferior olive reinnervate the denervated hemicerebellum. Unfortunately, reinnervation to the cerebellar hemisphere is incomplete; therefore, its capacity to mediate hemispheric function (navigation) is unknown. We studied sensorimotor control and spatial cognition of rats with and without transcommissural reinnervation using simple (bridge and ladder) and complex (wire) locomotion tests and the Morris water maze (hidden, probe and cued paradigms). Although pedunculotomized animals completed locomotory tasks more slowly than controls, all groups performed equally in the cued maze, indicating that lesioned animals could orientate to and reach the platform. In animals pedunculotomized on day 3 (Px3), which develop olivocerebellar reinnervation, final spatial knowledge was as good as controls, although they learned more erratically, failing to retain all information from one day to the next. By contrast, animals pedunculotomized on day 11 (Px11), which do not develop reinnervation, did not learn the task, taking less direct routes and more time to reach the platform than controls. In the probe test, control and Px3, but not Px11, animals swam directly to the remembered location. Furthermore, the amount of transcommissural reinnervation to the denervated hemisphere correlated directly with spatial performance. These results show that transcommissural olivocerebellar reinnervation is associated with spatial learning, i.e. even partial circuit repair confers significant functional benefit.

Inferior olivary inactivation abolishes conditioned eyeblinks: extinction or cerebellar malfunction?

The inferior olive (IO) is a required component of neural circuits controlling the classical conditioning of eyeblink responses. Previous reports indicated that lesioning or inactivating the IO abolishes conditioned eyeblinks (CRs), but there was disagreement regarding the timing of the CR performance deficit. As a result, it was not clear whether IO inactivation produces unlearning of CRs or a non-specific dysfunction of cerebellar circuits. Since most of these studies used methods that could block unrelated axons passing through the IO region, additional experiments are required to further elucidate IO function, using inactivating agents that act selectively on cell bodies. In the present study, the IO was inactivated using the glutamate receptor antagonist DGG and the GABA-A receptor agonist muscimol in rabbits performing well-learned CRs. Effects of inactivating the IO on CR expression and on neuronal activity in the anterior cerebellar interposed nucleus (IN) were examined. We found that either blocking excitatory glutamate inputs or activating inhibitory GABA inputs to the IO abolished CRs. This effect occurred with variable delay following drug injections. Additional experiments, in which post-injection testing was delayed to allow for drug diffusion, revealed invariably immediate suppression of CRs. This demonstrated that suppressing IO activity using DGG or muscimol does not induce unlearning of CRs. Single-unit recording during DGG injections revealed that CR suppression was paralleled by a dramatic suppression of IN neuronal activity. We concluded that inactivating the rostral parts of the IO complex abolishes CRs by producing a tonic malfunction of cerebellar eyeblink conditioning circuits.

Post-lesion transcommissural olivocerebellar reinnervation improves motor function following unilateral pedunculotomy in the neonatal rat

In the adult mammalian central nervous system, reinnervation and recovery from trauma are limited. During development, however, post-lesion plasticity may generate alternate paths providing models to investigate reinnervation and repair. Sometimes, these paths are maladaptive, although the relationship between dysfunction and anatomical abnormality remains unknown. After unilateral transection of the neonatal rat olivocerebellar path (pedunculotomy), axons from the remaining inferior olive reinnervate Purkinje cells in the denervated hemicerebellum with appropriate topography and synaptic function. However, whether this new pathway confers beneficial behavioural effects remains unknown. We studied the behavioural sequelae in rats with and without transcommissural reinnervation using righting and vestibular-drop reflexes, simple locomotion (bridge), complex locomotion (wire) and motor coordination (rotarod) tests. In animals pedunculotomised on day 3 (Px3), which develop olivocerebellar reinnervation, dynamic postural adjustments and complex motor skills develop normally, whereas simple gait is broad-based and slightly delayed. In contrast, Px11 animals, which do not develop reinnervation, have delayed maturation of postural reflexes, gait and complex locomotor skills. In addition, when compared to control animals, their performance in locomotory tasks was slower and the complex task impaired. On the rotarod, control and Px3 animals learned to coordinate their gait and walked for longer at 10 and 20 rpm than Px11 animals. These results show that transcommissural olivocerebellar reinnervation is associated with almost normal motor development and the ability to synchronise gait at slow and moderate speeds, i.e. this reinnervation confers significant behavioural function and is therefore truly compensatory.

Metabolic abnormalities caused by 3-acetylpyridine in the cerebral motor regions of rats: partial recovery by thyrotropin-releasing hormone

Although 3-acetylpyridine (3-AP) induces several motor disturbances and it degenerates the olivocerebellar pathway, abnormalities caused by 3-AP in cerebral motor regions remain to be elucidated. Here we investigated the metabolic changes caused by 3-AP (75 mg/kg, i.p.) on local cerebral glucose utilization (LCGU) in various brain regions. The effects of anti-ataxic agents, thyrotropin-releasing hormone (TRH) (10 mg/kg, i.p.) and its mimetic agent taltirelin hydrate (1 mg/kg, i.p.), on the 3-AP-induced change in LCGU were also investigated. The LCGU in the nuclei of the basal ganglia, thalamus, limbic structures and brainstem of 3-AP-treated rats was significantly lower than that of naive animals. However 3-AP increased the LCGU of the cerebellar nuclei. TRH restored depressed LCGU in the substantia nigra and ventral tegmental area. TRH tended to restore the lowered LCGU in several nuclei of 3-AP-treated rats. Moreover, taltirelin further increased the LCGU in the cerebellar nuclei. These results suggest that the motor disturbance of the 3-AP-treated rats may be due to not only degeneration of the olivocerebellar pathway but also dysfunction of the several areas that play a role in motor coordination. Moreover, the anti-ataxic action by TRH could result from metabolic restoration of the multiple motor-coordination-related areas.

Microinjections of anisomycin into the intermediate cerebellum during learning affect the acquisition of classically conditioned responses in the rabbit

The purpose of this study was to examine the effects of protein synthesis inhibition in the intermediate cerebellum on the acquisition and expression of classically conditioned nictitating membrane responses in the rabbit. Animals were conditioned for three days in a standard delay paradigm. Before each training session, either a solution of anisomycin (a protein synthesis inhibitor) or vehicle was bilaterally injected into the interposed cerebellar nuclear. Following these three training sessions, rabbits were tested to determine whether the previous training under the influence of anisomycin or vehicle resulted in the acquisition of conditioned responses. In this test, animals that were injected previously with the protein synthesis inhibitor exhibited significantly less retention of conditioned responses than rabbits injected with vehicle. Additional experiments demonstrated that anisomycin does not block the expression of conditioned responses during conditioning or in well-trained animals. Microinjections of muscimol at the same sites of the previous drug infusions suppressed the expression of conditioned responses, indicating that the protein synthesis inhibitor was applied to the eyeblink-related parts of cerebellar circuits. The obtained data are the first to demonstrate that a manipulation of cerebellar circuits, which does not affect the performance of learned behavior, can affect the process of learning. These results suggest that the synthesis of new proteins in the intermediate cerebellum participates in the formation of plastic changes responsible for eyeblink conditioning.

Role of the inferior olivary complex in motor skills and motor learning in the adult rat

The inferior olivary complex of adult rats was chemically destroyed using intraperitoneal injection of 3-acetylpyridine. Animals were submitted to different motor tasks: hanging test, equilibrium test and motor co-ordination test. The different scores show that 3-acetylpyridine-treated rats had motor co-ordination and static equilibrium deficiencies, whereas their rod suspension capabilities were intact. Animals were also trained on an unrotated rod or on a rod rotating at 5, 10 or 20 r.p.m. 3-Acetylpyridine-treated rats were able to maintain their equilibrium on the unrotated rod and at 5 r.p.m. Moreover, after motor training at 5 r.p.m., rats were able to improve their motor skills and reached the same score as controls. Despite their good motor skills, animals were unable to maintain their equilibrium when rotated at 10 and 20 r.p.m. These results suggest that the inferior olivary complex is needed for motor learning involving the temporal organization of movement.

Effects of lesion of the inferior olivary complex in learning of the equilibrium behavior in the young rat during ontogenesis. I. Total lesion of the inferior olive by 3-acetylpyridine

Young DA/HAN strain rats were submitted to an equilibrium test consisting in maintaining equilibrium upon a rotorod rotating at 10 or 20 rpm. They were either intact or lesioned, the lesion consisting in destruction of the inferior olivary complex (IOC) by 50-95 mg/kg i.p. administration of 3-acetylpyridine (3-AP) at day 15, followed, 2 to 4 h later, by i.p. injection of niacinamide (300 mg/kg). All the 3-AP-treated animals included in this study were completely lesioned, the extent of the lesion being estimated by both the response of the rats to harmaline and histological controls at the end of the experiments. The IOC lesioned rats were either naive (tested at one given day) or trained every day (10 trials per day); among the latters, some were trained before and after the lesion, the others being trained either before or only after. Control rats were submitted to the same training schedule. Both quantitative (time during which the animals maintained the equilibrium upon the rotating rod) and behavioral data (strategy used by the animals to maintain equilibrium) were obtained. The results demonstrate that, compared to those of controls rats, the quantitative and behavioral scores of the IOC lesioned animals were altered. Comparison of naive and trained animals shows that the impairment of the equilibrium behavior is not only due to the ataxia provoked by the IOC lesion but is also due to cognitive deficits. However, prelesion training facilitates the acquisition of a more efficient postlesion equilibrium behavior. From these results, it can be concluded that the olivo-cerebellar pathway is involved in the adaptation of motor behavior to the environmental conditions.

On the cerebellum, cutaneomuscular reflexes, movement control and the elusive engrams of memory

This review focuses on the role of the cerebellum in regulating cutaneomuscular reflexes and provides a hypothesis regarding the way in which this action contributes to the coordination of goal-directed movements of the extremities. Specific attention is directed towards the cerebellum's role in conditioned and unconditioned eyeblink reflexes and limb withdrawal reflexes as models of its interactions with the cutaneomuscular reflex systems. The implications regarding the cerebellum as a storage site for motor engrams also is discussed in the context of these two behaviors. The proposed hypothesis suggests that the cerebellum regulates important features of the cutaneomuscular reflex circuits including the integration of their activity with descending pathways in a manner that implements these fundamental reflex circuits in the organization and control of goal-directed movements of the extremities.

Reduction of GABAA and GABAB receptor densities in the cerebellar cortex from 3-acetylpyridine-induced ataxic rats

We measured GABAA and GABAB receptor densities in the cerebellar cortex from 3-acetylpyridine-induced ataxic rats using receptor autoradiography. GABAA and GABAB receptor densities were significantly reduced both in the molecular layer and the granule cell layer. Reduction of GABA receptor densities may be induced by loss of GABA receptors on the degenerated climbing fibers or by secondary or compensatory changes of neuronal activities in the cerebellum.

Effect of administration of 3-acetylpyridine followed by niacinamide injection on survival, extent of the inferior olivary complex lesion, and response to harmaline in the young rat

In the 15 day-old DA/HAN strained rat, i.p. injection of 3-acetylpyridine (3-AP) 50, 65 or 95 mg.kg-1 was followed 2 to 4 hours later by administration of niacinamide (300 mg.kg-1). The percentage of survival and the extent of the inferior olivary complex (IOC) lesion, determined histologically, were correlated with both the dose of 3-AP administered and the time delay between 3-AP and niacinamide injections. Moreover, the tremor elicited by harmaline was also correlated with the extent of the IOC lesion. The results show that it is more advantageous to administer 95 mg.kg-1 3-AP and to delay niacinamide injection by 2h30 or less to get the higher percentage of survival (about 90%) and a reasonably high percentage of totally IOC lesioned rats (more than 30%). They also demonstrate that the harmaline test is not sufficient to acutely judge of the extent of the IOC lesion and that, in all cases, histological controls have to be done. The results are discussed in terms of interrelationships of the variable studied.

Inferior olive serotonin and norepinephrine levels during development in the genetically dystonic rat

The dystonic (dt) rat is an autosomal recessive mutant with a motor syndrome that shares several features with idiopathic torsion dystonia in humans. In the dt rats, marked biochemical and physiological abnormalities have been localized to the olivo-cerebellar system. At the pharmacological level, the dt rats exhibit enhanced sensitivity to the behavioral effects of serotonergic (5HT) agonists, including quipazine, a drug that activates the neurons of the inferior olive (IO). High performance liquid chromatography with electrochemical detection was used to assay 5-HT, 5-hydroxyindoleacetic acid (5HIAA), and norepinephrine (NE) in micropunches of the IO in normal and dt rats at 14, 18 and 22 days of age. Samples of the rostral frontal lobes were used as internal controls. Significant age-dependent effects were seen on 5-HT and 5-HIAA levels in the IO, but not the frontal cortex, in both groups. Although both groups reached similar 5-HT levels by postnatal day 22, a significant interaction effect between age and phenotype indicated a difference in the pattern of development. Administration of quipazine (10 mg/kg, IP) to 18-day-old normal and dt rats 1 h prior to sacrifice caused significant reductions in NE, 5-HIAA and the ratio of 5-HIAA to 5-HT; however, no phenotypic differences were detected. The findings do not suggest that the differential behavioral responses to 5-HT agonists seen in normal and dt rats are the result of global abnormalities in 5-HT systems, nor do they suggest the presence of presynaptic defects in the IO.(ABSTRACT TRUNCATED AT 250 WORDS)

Reduction of GABA inhibition in Purkinje and cerebellar nuclei neurons in climbing fibre deafferented cerebella of rat

GABA agonists were iontophoretically applied to Purkinje cells (PCs) of the cerebellar cortex and to neurons of the cerebellar nuclei (NCNs) in normal and in climbing fibre (CF) deafferented cerebella of rat. The experiments were performed one and three months after CF deafferentation obtained by total inferior olive destruction with 3-acetylpyridine. All control PCs were dose-dependently inhibited by GABA and muscimol and nearly all by baclofen. After CF deafferentation, the number of PCs sensitive to muscimol remained the same but the number sensitive to baclofen was greatly reduced one month later and almost absent after three months. The number of NCNs inhibited by GABA was slightly reduced one month after deafferentation compared to controls, but reduced to less than half three months after. Thus CF deafferentation of the PC leads to changes in postsynaptic sensitivity to GABA, the presumed inhibitory neurotransmitter, affecting GABAA receptors of the NCNs and GABAB receptors of the PCs.

Rapid increases in cerebellar Purkinje cell glutamic acid decarboxylase (GAD67) mRNA after lesion-induced increases in cell firing

Loss of the inferior olive-climbing fiber input to the cerebellar cortex doubles the simple spike activity of the cerebellar Purkinje cell. There is a 3- to 4-fold increase in Purkinje cell messenger RNA for the 67 kDa form of glutamic acid decarboxylase (a synthetic enzyme for the neurotransmitter GABA) within 4-5 h of the increase in electrical activity, suggesting a rapid response of mechanisms influencing neurotransmitter synthesis or stability to altered electrophysiological activity.

Abnormal cerebellar output in rats with an inherited movement disorder

Biochemical and metabolic mapping techniques have consistently identified the deep cerebellar nuclei (DCN) of the genetically dystonic rat as a site of abnormality. Extracellular single-unit recording techniques were used to assess the functional significance of these findings in affected rats and normal littermates between 16 and 25 days of age. Cells in the medial nucleus of the mutant rats had significantly increased spontaneous firing rates in comparison with cells from normal rats. In both the medial and the interpositus nuclei, cells from the mutants fired more rhythmically than those from the normal rats. When harmaline was administered systemically to activate the olivo-cerebellar system, in normal rats, increased firing rate and bursting patterns of activity were seen. There was no reliable change in the average firing rate or rhythmicity of cells in the medial nucleus of the dystonic rats, although previous studies have shown that harmaline activates neurons in the inferior olive in the mutants. It is likely that naturally stimulated olivary activity also fails to modulate cerebellar output in this model of inherited movement disorder. Anatomical studies did not reveal any consistent changes in the number of Purkinje cells, the volume of the DCN, or the soma size of DCN neurons. Since the electrophysiological findings cannot be ascribed to a loss of the Purkinje cells that normally provide an inhibitory input to the cerebellar nuclei, the results of this study indicate the presence of a functional defect in the control of cerebellar output in the dystonic rat that accounts for the failure of these animals to display harmaline tremor and which may be critical to the motor syndrome.

GABA levels and GAD immunoreactivity in the deep cerebellar nuclei of rats with altered olivo-cerebellar function

Immunocytochemistry was used to examine the distribution, size, and density of glutamic acid decarboxylase immunoreactive (GAD+) puncta in two animal models with movement disorders, the genetically dystonic (dt) rat and rats with 3-acetylpyridine (3AP) lesions of the inferior olive. In both models, GAD activity is increased in the deep cerebellar nuclei (DCN) where the enzyme is localized primarily in the terminals of Purkinje cells. GABA levels were also measured in the DCN. The general distribution of GAD+ puncta in the DCN was similar in all groups. Immediately after the 3AP lesions, however, GABA levels were elevated in 3AP rats in comparison with both normal rats and age-matched dt rats. GAD+ puncta were also larger than normal in the 3AP group at this time, although the magnitude of this effect declined over a 2-week recovery period. Puncta density was decreased in the medial nucleus only in 25-day-old dt rats in comparisons with normal littermates. These findings are discussed in the context of previously reported differences in the firing rate of Purkinje cells in dt and 3AP-treated rats.

Tetrodotoxin induced calcium spikes: in vitro and in vivo studies of normal and deafferented Purkinje cells

Tetrodotoxin (TTX) is widely used to block the sodium dependent action potential in excitable cells to study their other ionic properties. TTX applied outside, selectively blocks voltage dependent sodium channels and is thought to have no other effects. We report here that TTX, applied to slices of rat cerebellum, suppressed sodium spikes of the Purkinje cells and induced firing in bursts of slower spikes. This activity was blocked by cobalt (2 mM) or cadmium (0.2 mM) in the medium as well as by hyperpolarizing currents showing that the slow spikes were due to voltage dependent calcium channels. The membrane potential was not significantly changed by TTX and the spikes during the bursts had the same threshold potentials and peak spike amplitudes as the voltage and Ca2+ dependent dendritic spikes evoked by injected current before adding TTX. This indicated that no marked changes in the membrane conductances were produced by the TTX. Unlike the burst firing induced by removing extracellular sodium, the TTX induced bursts were not followed by a large hyperpolarization. The same kind of results were obtained with extracellular recording in the in-vivo preparation with TTX applied topically or by pressure near the recording sites. TTX induced burst firing was not due to blocking afferent inhibitory input to the PC, since bicuculline (10(-6) M) applied without TTX, produced only increased firing of fast action potentials and no bursts. The bursts could be arrested within 1 to 2 min by intravenously administering 2 mg/kg sodium pentobarbital, the blockage lasted from 5 to 15 min.(ABSTRACT TRUNCATED AT 250 WORDS)

The structural and functional heterogeneity of glutamic acid decarboxylase: a review

Studies of the GABA-synthetic enzyme glutamate decarboxylase (glutamic acid decarboxylase; GAD; E.C.4.1.1.15) began in 1951 with the work of Roberts and his colleagues. Since then, many investigators have demonstrated the structural and functional heterogeneity of brain GAD. At least part of this heterogeneity derives from the existence of two GAD genes.

Decreased sensitivity of cerebellar nuclei neurons to GABA and taurine: effects of long-term inferior olive destruction in the rat

The effects of iontophoretically applying the presumed Purkinje cell inhibitory neurotransmitters, GABA and taurine, were tested on neurons of the cerebellar nuclei in normal and in climbing-fiber-deafferented cerebella. Rats treated with 3-acetylpyridine to totally destroy the inferior olive were used for acute experiments 105-185 days after treatment. In controls, nearly all neuronal firing was dose-dependently depressed by both inhibitory amino acids. The depression in firing for both were antagonized by bicuculline and picrotoxin but not by strychnine while TAG specifically antagonized only responses to taurine. At sufficient doses, bicuculline and TAG induced disinhibitory responses (significant release of neuron discharge) in the absence of applied antagonist. In deafferented animals, the inhibitory efficacy of GABA and taurine were drastically reduced; most of the neurons failed to respond to these amino acids at the same iontophoretic parameters as for the control rats. Moreover, high doses of bicuculline and TAG did not induce any disinhibitory response (no significant increase in discharge rate) in most of the neurons tested. These results clearly demonstrate that climbing fiber deafferentation reduces postsynaptic sensitivity of the cerebellar nuclei neurons for the presumed Purkinje cell inhibitory neurotransmitters.

Increased glutamic acid decarboxylase (GAD) mRNA and GAD activity in cerebellar Purkinje cells following lesion-induced increases in cell firing

Lesions of the inferior olive-climbing fiber projection to the cerebellar Purkinje cell were produced in adult rats using the neurotoxin 3-acetylpyridine. At 7 days post-lesion, glutamic acid decarboxylase (GAD) activity in Purkinje cell axons terminating in the lateral division of the deep cerebellar nucleus was significantly increased (+58%) above control levels. GAD mRNA levels in Purkinje cell bodies from the same animals were measured by in situ hybridization histochemistry using a radiolabeled cRNA probe for GAD mRNA. GAD mRNA was significantly elevated (+42%) above control at 7 days post-lesion. Because lesions of the climbing fiber system increase Purkinje cell firing rates, the results suggest that increased Purkinje cell activity induces transcription of GAD mRNA, which in turn results in increased GAD availability in Purkinje cell terminals.

Loss of N-methyl-D-aspartate sensitivity of cerebellar Purkinje cells after climbing fiber deafferentation. An in vivo study in the rat

The sensitivity of cerebellar Purkinje cells to brief iontophoretic applications of excitatory amino acids has been studied in vivo in rats treated from 15 days to 4 months beforehand with 3-acetylpyridine in order to destroy the inferior olive. Responses of Purkinje cells (PCs) chronically deprived of climbing fibers were thus investigated using extracellular microelectrodes and compared to those of a group of control rats. No changes in the relative efficiencies of L-glutamate, L-aspartate, quisqualate and kainate have been observed. In contrast, the excitations induced by N-methyl-D-aspartate (NMDA) on most PCs in control animals, were no longer present after climbing fiber deprivation. These results show that both NMDA and non-NMDA receptors are present on PCs of adult rodents and that the NMDA responses are strongly depressed when PCs are deafferented of the climbing fibers.

Persistent reduction of Purkinje cell inhibition on neurones of the cerebellar nuclei after climbing fibre deafferentation

The long lasting effects of inferior olive (IO) destruction were studied in rats treated with 3-acetylpyridine two years before. The activities of the Purkinje cells (PCs) and of their target neurones in the cerebellar nuclei (ECNs), were investigated and compared to those of a group of non-treated rats. Our results show that long-term deafferented PCs recovered a mean firing frequency similar to that of the controls while the ECNs discharge is enhanced. Furthermore, the cryodestruction of the cerebellar cortex produces a significant release of the ECNs firing in the control rats but not in the poisoned animals. Thus, it appears that IO destruction induces a permanent impairment of the inhibitory control exerted by the PCs on the activity of their target neurones.

The red nucleus activity in rats deprived of the inferior olivary complex

The long-term effects of the inferior olive destruction on the red nucleus activity, were studied in the rat following injection of 3-acetylpyridine. As soon as the olivary activity was suppressed, the discharge of the rubral units drastically decreased. Then, they progressively recovered the control frequency during the first month, although a normal rubral activity was not restored up to 8 months. The hypothesis is advanced that the olivocerebellar system is essential to shape the activity of the rubrospinal pathway.

Acute and chronic effects of climbing fiber lesions on cerebellar cyclic guanosine monophosphate

The neurotoxin 3-acetylpyridine was administered to 20-day-old rats to produce lesions of the inferior olive-climbing fiber projection to the cerebellum. Cerebellar cGMP levels were determined 6 h, 24 h, 48 h, 7 days, 14 days and 20 days postlesion. A significant effect on cGMP was found only at 48 h (-28%) and 7 days (-45%) postlesion. The results are discussed with respect to the cellular localization of cGMP and the hypothesized relationship of cGMP to cerebellar Purkinje cell activity.

Temporal sequence of motor disturbances and increased cerebellar glutamic acid decarboxylase activity following 3-acetylpyridine lesions in adult rats

Adult male rats were administered 75 mg/kg of the neurotoxin 3-acetylpyridine to produce lesions of the inferior olive-climbing fiber projection to the cerebellum. At selected times ranging from 6 h to 43 days postlesion, rats were evaluated for motor dysfunction, and glutamic acid decarboxylase (GAD) activity was determined in the deep cerebellar nuclei and cerebellar vermis. In the deep nuclei non-monotonic changes in GAD activity were found following climbing fiber destruction. Initially, there was a steady increase in GAD activity which peaked at 38% above control values 14 days postlesion. GAD activity then slowly declined, although it remained significantly above control levels at 43 days postlesion, the latest time point examined. In the vermis, GAD activity was significantly increased at 4 days postlesion (+8%) and remained at approximately this level throughout the experiment. The initial behavioral effects of climbing fiber loss included hypotonia and ataxia with severely reduced mobility. With time, the ataxia and hypotonia decreased and movements such as mud-walking and pivoting developed. As these behaviors diminished, other novel conditions such as movement-associated tremor and hopping appeared. These results are discussed in the context of the previously reported effects of climbing fiber lesions on the firing rates of Purkinje cells and deep nuclei cells.

Inferior olive lesion induces long-term modifications of cerebellar inhibition on Deiters nuclei

The frequency of discharge of cerebellar Purkinje cells and lateral vestibular nuclear cells were recorded at different intervals of time after injection of 3-acetylpyridine (3AP), which destroys the inferior olivary nucleus. During the first few days, Purkinje cells showed an increase of simple spike firing, while Deiters cells showed a strong depression of their discharge. Recordings up to 3 months demonstrated, for both groups of cells, a recovery, whose time course is faster for Deiters cells than for Purkinje cells. A reduced inhibitory efficacy of Purkinje cells, as a consequence of climbing fibre deprivation, is suggested.

Long term modification of rubral activity after inferior olive destruction

The long term effects of the inferior olive degeneration on red nucleus activity were studied in the rat. The animals were injected with 3-acetylpyridine to produce a pharmacological destruction of the inferior olive and were then used for acute experiments at 1-2, 5-7, 14-18, 29-37, 81-110 and 236-255 days later. After degeneration of the inferior olive, there was an 'initial period' lasting for a few days, characterized by a low discharge frequency of the red nucleus neurones. A 'period of adaptation' followed during the first month, characterized by a slow recovery towards the control firing rates of the rubral units. Nevertheless, the temporal distribution of the discharges was not recovered since the firing became organized in a bursting activity. From 1 up to 8 months, the normal unit activity was not restored. The hypothesis is advanced that the suppression of the inferior olive which increases the cerebellar inhibition, produces a consequent disfacilitation of red nucleus activity which persists for a few days. Then at increasing survival times, a progressive compensation takes place without a real restoration of the initial rubral activity.