The functional role of the nucleus accumbens in the control of the substantia nigra: electrophysiological investigations in intact and striatum-globus pallidus lesioned rats

Synchronized electrical stimulation of the rat medial forebrain bundle and perforant pathway generates an additive BOLD response in the nucleus accumbens and prefrontal cortex

To study how a synchronized activation of two independent pathways affects the fMRI response in a common targeted brain region, blood oxygen dependent (BOLD) signals were measured during electrical stimulation of the right medial forebrain bundle (MFB), the right perforant pathway (PP) and concurrent stimulation of the two fiber systems. Repetitive electrical stimulations of the MFB triggered significant positive BOLD responses in the nucleus accumbens (NAcc), septum, anterior cingulate cortex/medial prefrontal cortex (ACC/mPFC), ventral tegmental area/substantia nigra (VTA/SN), right entorhinal cortex (EC) and colliculus superior, which, in general, declined during later stimulation trains. At the same time, negative BOLD responses were observed in the striatum. Thus, the same stimulus caused region-specific hemodynamic responses. An identical electrical stimulation of the PP generated positive BOLD responses in the right dentate gyrus/hippocampus proper/subiculum (DG/HC), the right entorhinal cortex and the left entorhinal cortex, which remained almost stable during consecutive stimulation trains. Co-stimulation of the two fiber systems resulted in an additive activation pattern, i.e., the BOLD responses were stronger during the stimulation of the two pathways than during the stimulation of only one pathway. However, during the simultaneous stimulation of the two pathways, the development of the BOLD responses to consecutive trains changed. The BOLD responses in regions that were predominantly activated by MFB stimulation (i.e., NAcc, septum and ACC/mPFC) did not decline as fast as during pure MFB stimulation, thus an additive BOLD response was only observed during later trains. In contrast, in the brain regions that were predominantly activated by PP stimulation (i.e., right EC, DG/HC), co-stimulation of the MFB only resulted in an additive effect during early trains but not later trains. Consequently, the development of the BOLD responses during consecutive stimulations indicates the presence of an interaction between the two pathways in a target region, whereas the observed averaged BOLD responses do not.

The ventral basal ganglia, a selection mechanism at the crossroads of space, strategy, and reward

The basal ganglia are often conceptualised as three parallel domains that include all the constituent nuclei. The 'ventral domain' appears to be critical for learning flexible behaviours for exploration and foraging, as it is the recipient of converging inputs from amygdala, hippocampal formation and prefrontal cortex, putatively centres for stimulus evaluation, spatial navigation, and planning/contingency, respectively. However, compared to work on the dorsal domains, the rich potential for quantitative theories and models of the ventral domain remains largely untapped, and the purpose of this review is to provide the stimulus for this work. We systematically review the ventral domain's structures and internal organisation, and propose a functional architecture as the basis for computational models. Using a full schematic of the structure of inputs to the ventral striatum (nucleus accumbens core and shell), we argue for the existence of many identifiable processing channels on the basis of unique combinations of afferent inputs. We then identify the potential information represented in these channels by reconciling a broad range of studies from the hippocampal, amygdala and prefrontal cortex literatures with known properties of the ventral striatum from lesion, pharmacological, and electrophysiological studies. Dopamine's key role in learning is reviewed within the three current major computational frameworks; we also show that the shell-based basal ganglia sub-circuits are well placed to generate the phasic burst and dip responses of dopaminergic neurons. We detail dopamine's modulation of ventral basal ganglia's inputs by its actions on pre-synaptic terminals and post-synaptic membranes in the striatum, arguing that the complexity of these effects hint at computational roles for dopamine beyond current ideas. The ventral basal ganglia are revealed as a constellation of multiple functional systems for the learning and selection of flexible behaviours and of behavioural strategies, sharing the common operations of selection-by-disinhibition and of dopaminergic modulation.

Behavioural and physiological effects of electrical stimulation in the nucleus accumbens: a review

Electrical stimulation (ES) in the brain is becoming a new treatment option in patients with treatment-resistant obsessive-compulsive disorder (OCD). A possible brain target might be the nucleus accumbens (NACC). This review aims to summarise the behavioural and physiological effects of ES in the NACC in humans and in animals and to discuss these findings with regard to neuroanatomical, electrophysiological and behavioural insights. The results clearly demonstrate that ES in the NACC has an effect on reward, activity, fight-or-flight, exploratory behaviour and food intake, with evidence for only moderate physiological effects. Seizures were rarely observed. Finally, the results of ES studies in patients with treatment-resistant OCD and in animal models for OCD are promising.

Do silent dopaminergic neurons exist in rat substantia nigra in vivo?

A subpopulation of inactive or "silent" dopaminergic neurons has been reported to exist in vivo in rat substantia nigra, comprising up to 50% of nigral dopaminergic neurons. The existence of this large proportion of silent neurons has been inferred from various experimental manipulations, but never demonstrated directly. In the present study, striatal or medial forebrain bundle stimulation was used to activate antidromically substantia nigra dopaminergic neurons in vivo. Antidromic spikes of dopaminergic neurons observed by extracellular single-unit recordings in the absence of spontaneous activity were employed as indicators of the presence of a silent cell. A total of 312 dopamine neurons were recorded, including 190 neurons that could be antidromically activated from the striatum and/or the medial forebrain bundle. All neurons exhibited spontaneous activity. The firing rates were unimodally distributed about the mean of 4 spikes/s, and very few cells were observed to fire at less than 0.5 spikes/s. The numbers of spontaneously active and antidromically activated dopaminergic neurons per track were recorded and compared with the number of antidromically responding silent dopaminergic neurons per track after systemic apomorphine administration. Under control conditions, 0.80 +/- 0.10 or 1.36 +/- 0.13 spontaneously active neurons per track could be antidromically activated at 1.0 mA by striatal or medial forebrain bundle stimulation, respectively. After apomorphine completely suppressed spontaneous activity, 0.69 +/- 0.08 and 1.39 +/- 0.14 antidromic neurons per track were detected by stimulating the striatum or medial forebrain bundle respectively at 1.0 mA, demonstrating that silent dopaminergic neurons can be reliably identified through antidromic activation. In sharp contrast to previous reports, these data suggest that silent neurons do not comprise a substantial proportion of the total number of dopaminergic neurons in the substantia nigra. Reverse chi2 analysis revealed that, if they exist at all, silent dopaminergic neurons make up less than 2% of the dopaminergic cells in the substantia nigra. These findings are related to current theories of the mechanisms of action of antipsychotic drugs and the maintenance of near-normal levels of dopamine in the striatum following large-scale loss of nigral dopaminergic neurons.

Indirect nucleus accumbens input to the prefrontal cortex via the substantia nigra pars reticulata: a combined anatomical and electrophysiological study in the rat

The nucleus accumbens is a major component of the ventral striatum through which most of the limbic affiliated cortical areas gain access to the basal ganglia circuitry. In this study, the organization of the pathways linking the nucleus accumbens to the thalamus, via the substantia nigra pars reticulata, was examined in the rat using anatomical and electrophysiological methods. Use of anterograde and retrograde transport of wheatgerm agglutinin conjugated to horseradish peroxidase has established that the core of the nucleus accumbens innervates a dorsal region of the substantia nigra pars reticulata which projects to subfields of the mediodorsal and ventral medial thalamic nuclei. These subfields consist of the rostral pole of the mediodorsal nucleus with the exception of its central segment and a region of the ventral medial nucleus, medial to the mammillothalamic tract. Confirming the existence of a nucleus accumbens nigrothalamic link, we have observed that electrical or chemical stimulation of the nucleus accumbens induces an inhibition of the spontaneous discharges of the nigral cells which project to the mediodorsal and ventral medial thalamic nuclei. Finally, the cortical projections of the thalamic subfields involved in the nucleus accumbens nigrothalamic circuit were determined using the anterograde and retrograde axonal transport of wheatgerm agglutinin conjugated with horseradish peroxidase. These subfields innervate mainly the prelimbic and to a lesser degree the orbital areas of the prefrontal cortex. The present data show that the substantia nigra pars reticulata is a major link between the core of the nucleus accumbens and the prefrontal cortex and provide further evidence for the concept of a parallel architecture in the basal ganglia thalamocortical circuits of the ventral striatum.

Enhanced dopamine metabolism in accumbens leads to motor activity and concurrently to increased output from nondopamine neurons in ventral tegmental area and substantia nigra

We previously have reported that nondopamine (non-DA) neurons in substantia nigra (SN) and ventral tegmental area (VTA) of the rat show increased discharge rates during amphetamine (AMPH) and apomorphine (APO)-induced motor activity. The present study represents an attempt to determine the contribution of nucleus accumbens (ACC) dopaminergic activity to these effects, and to ascertain whether the effects in VTA differ from those seen in SN when dopaminergic activity is enhanced locally in ACC. The experiments were carried out in male albino rats (300-400 g) chronically implanted with multiple fine wire electrodes (62 microns) aimed at the pars reticulata of SN (SNR) and VTA. Unit activity was recorded extracellularly in the behaving rat, from neurons identified on the basis of the properties of their action potentials as representing the output of the non-DA neurons in these two structures. In each drug session, unit activity was recorded in parallel from several probes, while motor activity was measured with the open-ended wire technique. But with the recording technique used, a unit represented in most instances the output of a small family of neurons (3-10). Each animal underwent a series of tests given on consecutive days. During these tests, motor and unit activity were measured for 90 min before the drug was administered, and for 135 min after. The first test was of the effects of AMPH, 5 mg/kg, given by the systemic route. The second was of the effects of saline containing 0.1% ascorbic acid (the vehicle) injected bilaterally in ACC, in a volume of 2 microliters per side. The third and all subsequent tests were of the effects of a mixture containing 40 micrograms AMPH, 20 micrograms DA, and 20 micrograms pargyline (P) dissolved in 2 microliters of the vehicle, injected bilaterally in ACC. The results showed that systemic AMPH made the animal hyperactive and at the same time, increased the discharge rate of the non-DA neurons. The bilateral injections of the vehicle in ACC, increased motor activity for about 7 min, an effect interpreted as a rebound from the restraint of the animal during the intracerebral injections, and then depressed motor throughout the 135 min of the postinjection recording period. The effect of the vehicle was to depress unit activity. The effects of injecting the mixture in ACC was to increase motor activity, but with the magnitude and duration of the increase depending on the number of treatments received.(ABSTRACT TRUNCATED AT 400 WORDS)

Action of nicotine on accumbens dopamine and attenuation with repeated administration

The behavioral and physiological effects of repeated nicotine administration are complex; sedation and hypothermia are present early but become attenuated while locomotor activity increases. Maximal blood levels and behavioral changes occur within 10 min of s.c. injection. We examined the effects of 10 nicotine injections (0.8 mg/kg) in 14 days on the levels of brain amines following challenge with either saline or nicotine on the 15th day. Dopamine, DOPAC, HVA, 3-methoxytyramine, norepinephrine, 5-hydroxytyramine, and 5-HIAA were measured in the frontal cortex, olfactory tubercle, nucleus accumbens, caudate-putamen, substantia nigra and ventral tegmental area. Ten minutes after nicotine was given to rats that had previously received only saline the levels of dopamine and its metabolite DOPAC indicated an increase in dopamine turnover in the nucleus accumbens. Of the areas examined the accumbens was the most sensitive to nicotine, with few significant amine changes in other regions. Twenty-four hours after the last nicotine injection the levels of dopamine and its metabolites indicated a sustained decrease in dopamine turnover in the accumbens induced by repeated administration. Following repeated nicotine a nicotine challenge still induced an acute increase in dopamine turnover in the accumbens, but the response was less than in animals not previously given nicotine. The results confirm earlier studies indicating that the accumbens is a major site of nicotine action.

Cholecystokinin antagonist lorglumide reverses chronic haloperidol-induced effects on dopamine neurons

Intravenous administration of the cholecystokinin (CCK) antagonist lorglumide (LORG) reversed chronic haloperidol (CHAL)-induced depolarization inactivation (DI) of dopamine (DA) cells in both the A9 and A10 areas. Moreover, microinjection of LORG, but not naloxone, directly into the medial nucleus accumbens (mNAc) dose-dependently reversed CHAL-induced effect. LORG injected into other brain regions was without effect. These results suggest that CCK receptors in the mNAc form an important link for maintaining CHAL-induced DI of DA cells and that CCK is involved in the therapeutic action of antipsychotic drugs.

The response of non-dopamine neurons in substantia nigra and ventral tegmental area to amphetamine and apomorphine during hypermotility: the striatal influence

The effects of haloperidol pretreatment in striatum on the motor response, and on concurrently recorded unit responses of nondopamine (DA) neurons in substantia nigra (SN) and ventral tegmental area (VTA) to systemic amphetamine and apomorphine, were investigated with the objective of determining the role of the striatum in the output of putative DA output neurons. Unit and motor activity were recorded in the male rat, chronically implanted with 9 electrodes in SN and VTA and with two cannulae for bilateral injections into striatum. The recording electrodes were 3 bundles of 3 wires, each wire in the bundle of a different length, but all 3 aimed at SN, pars reticulata, or VTA. In each recording session, unit activity was derived from 7 wires while gross motor activity was recorded with the open-ended wire technique. The subjects were tested under two conditions. In the first, the vehicle was injected bilaterally into striatum 90 min before one of the DA agonists was injected by the intraperitoneal route. In the second, the DA antagonist haloperidol was injected bilaterally into striatum before the systemic treatment with the DA agonist. In subjects which received injections of the vehicle into striatum, amphetamine induced a large motor response, and concurrently, a large increase in the rate of discharge of a portion of the identified non-DA neurons in SN and VTA. In subjects which received injections of haloperidol into striatum, amphetamine induced a smaller behavioral response, a smaller increase in the rate of discharge of these neurons in SN but not in VTA where the increase was of the same magnitude as controls. In control subjects, apomorphine induced an increase in motor activity and concurrently, an increase in the rate of firing of the identified non-DA neurons in SN and VTA. But the increases were of somewhate smaller magnitude and much shorter duration than the increases induced by amphetamine. In subjects which had been pretreated with haloperidol in striatum, apomorphine induced an increase in motor activity that was of the same magnitude as the insion that the striatum has the capacity to influence the output of non-DA neurons only in SN but also in VTA, indicating that, if there is a specialization of function, it is only relative.(ABSTRACT TRUNCATED AT 400 WORDS)

Amphetamine-induced increase in motor activity is correlated with higher firing rates of non-dopamine neurons in substantia nigra and ventral tegmental area

The responses of non-dopamine neurons in substantia nigra and ventral tegmental area to systemic amphetamine were investigated in the behaving rat chronically implanted with multiple fine-wire electrodes. The neurons were identified with electrophysiological criteria requiring that the signals be of biphasic shape, short duration (less than 2.0 ms), and show high and regular rates of discharge (greater than 20 spikes/s). In recording sessions lasting 240 min, single and multiple unit activity was recorded from seven electrodes, and motor activity was measured automatically with the open-ended wire technique. The movement counts provided an index of gross motor activity, not of the specific movements occurring during DA behaviors. D-Amphetamine, 5.0 mg/kg, given by the intraperitoneal route at 90 min into the session, induced an increase in motor activity and in the firing rate of some non-dopamine neurons. The behavioral and neural responses were correlated for magnitude, latencies and duration. But not all non-dopamine neurons in ventral tegmental area, and substantia nigra showed responses to amphetamine. When unit responses were obtained, they were obtained in subjects which showed large motor responses. In substantia nigra, responsive and non-responsive units were interdigitated and found mainly in the pars reticulata subdivision. In the ventral tegmental area, responsive and non-responsive neurons were interdigitated throughout this structure. The effects of amphetamine were dose-responsive, doses of 1.0, 2.0 and 3.0 mg/kg inducing smaller behavioral and unit responses than 5.0 mg/kg. D-Amphetamine, 5.0 mg/kg, was more effective than L-amphetamine, given at the same dose, in inducing these changes. In rats pretreated with systemic haloperidol, 1.5 mg/kg, the behavioral and neural responses to D-amphetamine, 5.0 mg/kg, were greatly attenuated. In rats pretreated with a subanesthetic dose of urethan, 600 mg/kg, to prevent changes in gross motor activity, the response to D-amphetamine in ventral tegmental area was attenuated, but it was of normal magnitude in substantia nigra. In rats with bilateral electrolytic lesions of nucleus accumbens, D-amphetamine induced a smaller motor response than in controls, but the neural responses in ventral tegmental area and substantia nigra were the same as in controls. These findings support the notion that non-dopamine neurons in ventral tegmental area and substantia nigra, pars reticulata, play a role in the motor function of the A9 and A10 dopamine neurons, and in the behavioral effects of amphetamine.(ABSTRACT TRUNCATED AT 400 WORDS)

Differential effects of acute clozapine and haloperidol on the activity of ventral tegmental (A10) and nigrostriatal (A9) dopamine neurons

Extracellular single-unit recording techniques were used to evaluate the effects of acute intravenous (i.v.) clozapine (CLOZ) and haloperidol (HAL) on the activity of dopamine (DA) neurons of the ventral tegmental area (VTA or A10) and the substantia nigra pars compacta (SNC or A9). CLOZ increased the firing rate of A10 but not A9 cells, and drove 9/23 (39%) of A10 cells into an apparent depolarization blockade. HAL, on the other hand, produced a rate elevation and, at higher doses, depolarization inactivation in both subpopulations of DA neurons. Cell firing was restored in inactivated cells with i.v. apomorphine (APO) or iontophoretic GABA. CLOZ always fully reversed APO-induced suppression of A10 DA activity, but in many cases only partially reversed suppression of A9 DA neurons. Scopolamine did not mimic the effects of CLOZ on A10 neurons, and it also failed to block the activating effect of HAL on A9 units, indicating that the selective action of CLOZ cannot be interpreted simply by its anticholinergic properties. After hemi-transections of the diencephalon, which severed the medial forebrain bundle and other feedback pathways to the DA somata, CLOZ was still ineffective in altering A9 DA activity. This suggests that the lack of effect on CLOZ on A9 cells is not due to the inhibitory influence of forebrain feedback pathways. This hemi-transection also left intact the activation of A10 neurons produced by HAL and CLOZ, but it did prevent the excitatory action of HAL on most A9 neurons sampled. This indicates that forebrain feedback pathways are less critical in mediating the action of APDs on A10 DA neurons. Finally, iontophoretic application of CLOZ and HAL into the vicinity of DA cell bodies blocked the rate-reducing effects of locally applied DA, but not those of GABA. This suggests that both APDs block somatodendritic DA autoreceptors. However, HAL was considerably more potent than CLOZ in producing this blockade. It is suggested that the different pharmacological and clinical properties of HAL and CLOZ may be partially explained by a differential mode of action on the A10 and A9 subpopulations of DA cells. The data also provide pharmacological evidence that these 2 groups of DA cells are regulated by different mechanisms.

A lesioning and 2-deoxyglucose study of the hyperactivity produced by an intra-accumbens dopamine agonist

Lesioning and 2-deoxyglucose (2-DG) autoradiographic studies were applied to the hyperactivity induced in rats by intra-accumbens treatment with the dopamine agonist 2-amino-6,7-dihydroxy-1,2,3,4-tetrahydro-naphthalene (ADTN). Lesions made in substantia innominata and rostro-ventral globus pallidus both attenuated the hyperactivity although no consistent changes in 2-DG uptake were recorded in these areas. Compared to normal rats, hyperactive rats showed greatly increased glucose utilization in the subthalamic nucleus and lateral habenula. Lesioning the subthalamic nucleus greatly reduced the hyperactivity, whereas a lateral habenula lesion was ineffective. Hyperactivity was associated with a discrete, bilateral area of increased 2-DG uptake in the reticular formation which corresponded to the description of the deep mesencephalic nucleus (DMN). Lesions made in the DMN greatly attenuated the hyperactivity response. The DMN may be a locomotor region in the rat.

Pedunculopontine-evoked excitation of substantia nigra neurons in the rat

The effects of electrical stimulation of the nucleus tegmenti pedunculopontinus on the unitary activity of identified neurons of the rat substantia nigra were studied. The experiments were carried out in intact rats as well as in animals bearing either chronic bilateral electrolytic lesions of the deep cerebellar nuclei or an acute lesion of the ipsilateral subthalamic nucleus. Excitation of both compacta and reticulata cells of the substantia nigra (many of the latter being output neurons since they are antidromically activated from the superior colliculus) was the predominant response recorded. Two types of excitations could be distinguished. The first was a direct orthodromic excitation (latency 2.9 +/- 1.6 ms; duration 3.7 +/- 1.9 ms). The second was a sparse and less pronounced activation (latency 5.2 +/- 1.8 ms; duration 13.0 +/- 3.0 ms). These two types of excitation were the only responses recorded in intact rats (10/51, 19.6%, orthodromic and 10/51, 19.6%, diffuse activation). When the cerebellar nuclei were destroyed 7-21 days prior to the recording, both excitations were still found (10/59, 16.9% and 15/59, 25.4%, respectively), whereas a minority (3/59, 5.0%) of neurons were inhibited. Conversely, when the subthalamic nucleus was lesioned the orthodromic response was still present (9/42, 21.4%) whereas the occurrence of the diffuse excitation greatly decreased (3/42, 7.1%) and a greater number of inhibitions (6/42, 14.2%) appeared. A small population of cells (12/85, 14.1%) were excited from the contralateral pedunculopontine nucleus either by the orthodromic or by the diffuse excitation. The total number of nigral neurons antidromically activated from the ipsilateral pedunculopontine nucleus was 9/152 (5.9%). The results provide evidence that the nucleus tegmenti pedunculopontinus gives a dual excitatory input to the substantia nigra either through a probable direct connection or through a polysynaptic pathway via the subthalamic nucleus. A few cells from both parts of the substantia nigra, in turn, project back to the nucleus tegmenti pedunculopontinus. In addition, our data give further support to the view that output fibers from the deep cerebellar nuclei do not synapse in the substantia nigra in the rat.

Neurotransmitters in the basal ganglia

The literature is reviewed on the afferents and efferents of the caudate/putamen, globus pallidus and substantia nigra, and on the neurotransmitters occurring in the various tracts. Emphasis is placed upon the diverse roles played by GABA and glutamate as transmitters in motor pathways and upon the probability that the substantia nigra pars reticulata plays a pivotal role in the output of the basal ganglia. Excessive stimulation of the projection from the pedunculopontine tegmental area to the substantia nigra is shown to cause destruction of dopaminergic neurons in the latter nucleus, suggesting another possible mechanism for cell death in Parkinson's disease.