Apomorphine decreases extracellular GABA in the ventral pallidum of rats with 6-OHDA lesions in the nucleus accumbens

GABAB receptor activation attenuates the stimulant but not mesolimbic dopamine response to ethanol in FAST mice

Neural processes influenced by γ-aminobutyric acid B (GABA(B)) receptors appear to contribute to acute ethanol sensitivity, including the difference between lines of mice bred for extreme sensitivity (FAST) or insensitivity (SLOW) to the locomotor stimulant effect of ethanol. One goal of the current study was to determine whether selection of the FAST and SLOW lines resulted in changes in GABA(B) receptor function, since the lines differ in sensitivity to the GABA(B) receptor agonist baclofen and baclofen attenuates the stimulant response to ethanol in FAST mice. A second goal was to determine whether the baclofen-induced reduction in ethanol stimulation in FAST mice is associated with an attenuation of the mesolimbic dopamine response to ethanol. In Experiment 1, the FAST and SLOW lines were found to not differ in GABA(B) receptor function (measured by baclofen-stimulated [(35)S]GTPγS binding) in whole brain or in several regional preparations, except in the striatum in one of the two replicate sets of selected lines. In Experiment 2, baclofen-induced attenuation of the locomotor stimulant response to ethanol in FAST mice was not accompanied by a reduction in dopamine levels in the nucleus accumbens, as measured by microdialysis. These data suggest that, overall, GABA(B) receptor function does not play an integral role in the genetic difference in ethanol sensitivity between the FAST and SLOW lines. Further, although GABA(B) receptors do modulate the locomotor stimulant response to ethanol in FAST mice, this effect does not appear to be due to a reduction in tonic dopamine signaling in the nucleus accumbens.

Quinelorane, a dopamine D3/D2 receptor agonist, reduces prepulse inhibition of startle and ventral pallidal GABA efflux: time course studies

Startle is inhibited when the startling stimulus is preceded 30-300 ms by a weak prepulse. Prepulse inhibition (PPI), an operational measure of sensorimotor gating, is deficient in schizophrenia patients, and reduced in rats and humans by dopamine agonists. The neural basis for the PPI-disruptive effects of dopamine agonists in rats is studied to understand neural circuitry regulating PPI and its deficits in schizophrenia. Existing data suggest that ventral pallidal (VP) GABAergic transmission regulates PPI and its disruption by dopamine agonists. We measured changes in VP GABA efflux and PPI in rats in response to the D2/D3 agonist, quinelorane. Wistar rats were administered quinelorane (vehicle, 0.003 or 0.01 mg/kg). In some rats, VP dialysate was analyzed for GABA content. In others, PPI was assessed using 120 dB(A) startle pulses and prepulses 10 dB over a 70 dB(A) background. Quinelorane reduced GABA efflux, with significant effects for 0.01 but not 0.003 mg/kg, persisting for at least 100 min. Quinelorane reduced PPI for 50 min, an effect significant for both the 0.003 (p < 0.05) and 0.01 mg/kg doses (p < 0.015). Differences in time course and dose sensitivity of quinelorane effects on VP GABA efflux and PPI are discussed.

Extracellular hypothalamic gamma-aminobutyric acid (GABA) and L-glutamic acid concentrations in response to bicuculline in a genetic absence epilepsy rat model

The posterior part of the hypothalamus plays a vital role in the homeostatic processes of the internal environment, including blood pressure and heart rate regulation, by means of gamma-aminobutyric acid (GABA)ergic and glutamatergic neurotransmission. In this study we measured the extracellular levels of GABA and L-glutamic acid in the dorsomedial hypothalamic nucleus (DMH) and posterior hypothalamus (PH), following intracerebroventricular (i.c.v.) administration of bicuculline, a GABA(A)-receptor antagonist, in genetic absence epileptic rats from Strasbourg (GAERS), where heart rate, blood pressure, and EEG recordings were also collected simultaneously. The i.c.v. injection of bicuculline (0.3 nmol) produced no response in non-epileptic Wistar rats but caused an increase in mean arterial pressure in GAERS (P<0.01). Microdialysis experiments showed that L-glutamic acid increased in the DMH in GAERS after bicuculline administration (P<0.01). Additionally, extracellular GABA concentration decreased in the PH (P<0.05). Bicuculline suppressed the spike-and-wave discharges, the characteristic sign of absence seizures. All these results suggest that the bicuculline-induced blood pressure response is accompanied by changes in L-glutamic acid levels in the DMH and GABA levels in the PH, indicating a bicuculline hypersensitivity in the DMH and PH of GAERS that may make the GAERS display an altered mode of central cardiovascular regulation. These results suggest that the circuits affected in GAERS are not only restricted to the regions responsible for seizure generation but also present in the hypothalamus.

Cannabinoid modulation of opiate reinforcement through the ventral striatopallidal pathway

Recent evidence indicates that cannabinoid-1 (CB1) receptors play a role in the mediation of opiate reward, though the neural mechanisms for this process have not been characterized. The present experiments investigated the influence of CB1 receptors in the ventral striatopallidal system on opiate-induced neurochemical events and opiate self-administration behavior in rats. Acute morphine administration (3 mg/kg) significantly reduced ventral pallidal GABA efflux in a manner similar to that produced by heroin self-administration. This neurochemical effect was reversed by doses of the selective CB1 antagonist SR 141716A (Rimonabant; 1 and 3 mg/kg) that also significantly reduce opiate reward. Morphine-induced increases in nucleus accumbens dopamine levels were unaltered by SR 141716A. Intravenous heroin self-administration (0.02 mg/infusion) was significantly reduced by intra-accumbens, but not intraventral pallidal SR 141716A infusions (1 and 3 microg/side), implicating nucleus accumbens CB1 receptors in the modulation of opiate reinforcement. In contrast, SR14716A did not alter cocaine self-administration (0.125 mg/inf), cocaine-induced (10 mg/kg) decrements in ventral pallidal GABA efflux or cocaine-induced increases in accumbens dopamine. This is consistent with evidence that selective inactivation of CB1 receptors reduces opiate-, but not psychostimulant-maintained self-administration. The CB1 receptor agonist WIN 55,212-2 (5 mg/kg) reduced pallidal GABA efflux in a manner similar to morphine, and this effect was reversed by the opiate receptor antagonist naloxone. Collectively these findings suggest that CB1 receptors modulate opiate reward through the ventral striatopallidal projection and that the modulation of this projection system may be involved in the reciprocal behavioral effects between cannabinoids, and opioids.

Time-dependent recovery from the effects of 6-hydroxydopamine lesions of the rat nucleus accumbens on cocaine self-administration and the levels of dopamine in microdialysates

RATIONALE

Neurotoxin induced lesions of dopamine-releasing neurons that innervate the nucleus accumbens (NAcc) alter cocaine self-administration. In addition, elevated extracellular levels of NAcc dopamine (DA) are thought to be central to the biological mechanisms that underlie this behavior.

OBJECTIVES

This study assessed the long-term effects of 6-hydroxydopamine (6-OHDA) induced lesions of the NAcc on cocaine self-administration and the dialysate levels of dopamine ([DA](d)) in this structure to determine if recovery of drug intake was correlated with the DA response.

METHODS

Rats implanted with jugular catheters and bilateral cannulas were trained to self-administer cocaine and subsequently received bilateral intracranial micro-injections of 6-OHDA or vehicle into the NAcc. The levels of DA and cocaine were determined in microdialysates of the NAcc collected during experimental sessions 6-7, 14-16, 29-30, and 44-46 days post-treatment.

RESULTS

The 6-OHDA induced lesions significantly reduced cocaine self-administration for 3 weeks while vehicle treatment had a moderate effect for the first several days. Cocaine-induced increases in NAcc [DA](d) did not return to sham/vehicle treated control levels for 6 weeks in the lesioned group and DA content in the NAcc was 46% of control at 44 days post-lesion.

CONCLUSIONS

Although dopaminergic lesions of the NAcc produced profound effects on cocaine self-administration, responding recovered to control levels before cocaine-induced increases in NAcc [DA](d) while content of DA in the NAcc did not recover. These data suggest that the plasticity of neuronal systems in the NAcc related to cocaine self-administration and their response following 6-OHDA lesions is more complex than restoration of DAergic tone.

GABA transmission in the ventral pallidum is not involved in the control of latent inhibition in the rat

Latent inhibition describes a process of learning to ignore stimuli of no consequence, and is disrupted in acute, positive-symptomatic schizophrenia. Understanding the neural basis of latent inhibition in animals may help to elucidate the neural dysfunction underlying positive schizophrenic symptoms in man. Evidence suggests a crucial role for dopamine transmission in the nucleus accumbens in the control of latent inhibition. The present studies investigated the role of the GABA-ergic efferent from the nucleus accumbens to the ventral pallidum in latent inhibition. The GABA(A) agonist muscimol (4.56 ng/microl), and antagonist picrotoxin (0.2 microg/microl), were infused into the ventral pallidum, and effects on latent inhibition were assessed using a conditioned suppression procedure. Neither drug produced specific effects on latent inhibition when given alone and, in the case of muscimol, failed to reverse the disruption of latent inhibition induced by systemic amphetamine. In addition to significant non-specific drug effects, a positive control experiment revealed that intra-pallidal picrotoxin significantly enhanced locomotion, suggesting that our manipulations of ventral pallidal GABA function were behaviourally effective. We conclude that modulating ventral pallidal GABA transmission does not affect latent inhibition. The implications of this finding for theories of the neural circuitry mediating latent inhibition and for understanding the functional role of ventral pallidal GABA transmission are discussed.

Effect of intracerebral administration of NMDA and AMPA on dopamine and glutamate release in the ventral pallidum and on motor behavior

The present study investigates the modulation of the ventral tegmental area (VTA)-ventral pallidum (VP) dopaminergic system by glutamate agonists in rats. The glutamate receptor agonists N-methyl-D-aspartate (NMDA) and alpha-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid (AMPA) were infused via reversed microdialysis into the VTA, and dopamine (DA), glutamate, and aspartate levels in the VTA and ipsilateral VP were monitored together with motor behavior screened in an open field. NMDA (750 microM) infusion, as well as AMPA (50 microM) infusion, induced an increase of DA and glutamate levels in the VTA, followed by an increase of DA levels in the ipsilateral VP and by enhanced locomotor activity. The increase of DA in the VP was similar after administration of these two glutamate agonists, although motor activity was more pronounced and showed an earlier onset after NMDA infusion. Glutamate levels in the VP were not increased by the stimulation of DA release. It is concluded that DA is released from mesencephalic DA neurons projecting to the VP and that these neurons are controlled by glutamatergic systems, via NMDA and AMPA receptors. Thus, DA in the VP has to be considered as a substantial modulator. Dysregulation of the mesopallidal DA neurons, as well as their glutamatergic control, may play an additional or distinct role in disorders like schizophrenia and drug addiction.

Cortical cholinergic inputs mediating arousal, attentional processing and dreaming: differential afferent regulation of the basal forebrain by telencephalic and brainstem afferents

Basal forebrain corticopetal neurons participate in the mediation of arousal, specific attentional functions and rapid eye movement sleep-associated dreaming. Recent studies on the afferent regulation of basal forebrain neurons by telencephalic and brainstem inputs have provided the basis for hypotheses which, collectively, propose that the involvement of basal forebrain corticopetal projections in arousal, attention and dreaming can be dissociated on the basis of their regulation via major afferent projections. While the processing underlying sustained, selective and divided attention performance depends on the integrity of the telencephalic afferent regulation of basal forebrain corticopetal neurons, arousal-induced attentional processing (i.e. stimulus detection, selection and processing as a result of a novel, highly salient, aversive or incentive stimuli) is mediated via the ability of brainstem ascending noradrenergic projections to the basal forebrain to activate or "recruit" these telencephalic afferent circuits of the basal forebrain. In rapid eye movement sleep, both the basal forebrain and thalamic cortiocopetal projections are stimulated by cholinergic afferents originating mainly from the pedunculopontine and laterodorsal tegmenta in the brainstem. Rapid eye movement sleep-associated dreaming is described as a form of hyperattentional processing, mediated by increased activity of cortical cholinergic inputs and their cortical interactions with activated thalamic efferents. In this context, long-standing speculations about the similarities between dreaming and psychotic cognition are substantiated by describing the role of an over(re)active cortical cholinergic input system in either condition. Finally, while determination of the afferent regulation of basal forebrain corticopetal neurons in different behavioral/cognitive states assists in defining the general cognitive functions of cortical acetylcholine, this research requires a specification of the precise anatomical organization of basal forebrain afferents and their interactions in the basal forebrain. Furthermore, the present hypotheses remain incomplete because of the paucity of data concerning the regulation and role of basal forebrain non-cholinergic, particularly GABAergic, efferents.

Basal forebrain afferent projections modulating cortical acetylcholine, attention, and implications for neuropsychiatric disorders

Cortical acetylcholine (ACh) mediates the detection, selection, and processing of stimuli and associations, and the allocation of processing resources for these attentional functions. For example, loss of cortical cholinergic inputs impairs the performance of rats in tasks designed to assess sustained or divided attention. Intrabasalis infusions of benzodiazepine receptor (BZR) agonists block increases in cortical ACh efflux and impair attentional abilities. Studies on the regulation of cortical ACh efflux by nucleus accumbens (NAC) dopamine (DA) demonstrate that increases in cortical ACh efflux are attenuated by intra-accumbens administration of D1 and, more potently, D2 receptor antagonists. These and other data support the hypothesis that NAC DA, via GABAergic projections to the basal forebrain, controls the excitability of basal forebrain cholinergic neurons. As increases in NAC DA have been hypothesized to represent a major neuronal mediator of schizophrenia and the compulsive use of addictive drugs, the data predict that the abnormal regulation of cortical ACh release represents a crucial neuronal mechanism mediating the cognitive components of these psychopathological disorders.

Role of accumbens and cortical dopamine receptors in the regulation of cortical acetylcholine release

Cortical acetylcholine, under resting and stimulated conditions, was measured in frontoparietal and prefrontal cortex using in vivo microdialysis in freely-moving rats. Cortical acetylcholine efflux was stimulated by systemic administration of the benzodiazepine receptor partial inverse agonist FG 7142. Administration of FG 7142 (8.0 mg/kg; i.p.) significantly elevated acetylcholine efflux in both cortical regions (150-250% relative to baseline) for 30 min after drug administration. The ability of endogenous dopamine to regulate cortical acetylcholine efflux under resting or stimulated conditions and the relative contributions of D1- and D2-like dopamine receptor activation was also assessed. In a first series of experiments, systemic administration of the antipsychotic drug haloperidol (0.15, 0.9 mg/kg, i.p.) blocked FG 7142-stimulated acetylcholine efflux in frontoparietal, cortex while the D1-like antagonist, SCH 23390 (0.1, 0.3 mg/kg), was less effective in attenuating stimulated acetylcholine efflux. In a second series of experiments, the effects of infusions of these antagonists and of the D2-like antagonist sulpiride (10, 100 microM) into the nucleus accumbens were assessed. Infusions of haloperidol and sulpiride significantly blocked FG 7142-stimulated acetylcholine efflux while SCH 23390 did not. By contrast, a third series of experiments demonstrated that perfusion of these antagonists (100 microM) locally into the cortex (through the probe) did not affect FG 7142-stimulated acetylcholine efflux. Moreover, none of these dopamine receptor antagonists, whether administered systemically or perfused into the nucleus accumbens or cortex, affected basal cortical acetylcholine efflux. These results reveal similarities in stimulated cortical acetylcholine release across frontal cortical regions and suggest a prominent role for D2-mediated accumbens dopamine transmission in the regulation of cortical acetylcholine release. The findings provide evidence in support of a neural substrate that links dysregulation of mesolimbic dopaminergic transmission to changes in cortical cholinergic transmission. Dysregulation within this circuit is hypothesized to contribute to the etiology of disorders such as schizophrenia, dementia and drug abuse.

Abnormal regulation of corticopetal cholinergic neurons and impaired information processing in neuropsychiatric disorders

Cholinergic neurons originating in the basal forebrain innervate all cortical areas and participate in the gating of cortical information processing. Aberrations in the excitability of cortical cholinergic inputs fundamentally alter the processing of sensory stimuli and higher processes, thereby advancing the development of major neuropsychiatric disorders. Cortical cholinergic deafferentation has been considered to be a major neuropathological variable that contributes to the development of age- and dementia-associated impairments in cognition. Conversely, it has been suggested that increases in the excitability of cortical cholinergic inputs mediate the abnormal cognitive processes that escalate into psychotic symptoms and contribute to addictive-drug-seeking behavior, anxiety and phobia. Abnormal regulation of the excitability of cortical cholinergic afferents represents a 'final common pathway' that mediates the manifestation of major neuropsychiatric disorders.

Depletion of dopamine in the nucleus accumbens prevents the generation of locomotion by metabotropic glutamate receptor activation

The contribution of dopamine (DA) to the locomotion elicited by activation of nucleus accumbens (NAcc) metabotropic glutamate receptors (mGluRs) was investigated in the rat. Different groups of rats were pretreated with bilateral microinjections of either 6-hydroxydopamine (6-OHDA) or its vehicle into the NAcc and, on separate tests starting 10 days later, were tested for locomotion following microinjections (into the same site) of saline, the mGluR agonist, 1-aminocyclopentane-trans-1,3-dicarboxylic acid [(1S, 3R)-ACPD, 0.5 nmol/side] and amphetamine (AMPH, 6.8 nmol/side). DA levels at the microinjection sites were significantly depleted in 6-OHDA-treated rats (42-99% depletions compared to control values obtained in vehicle-treated rats). In contrast to the increased locomotion observed in non-lesioned animals, rats pretreated with 6-OHDA showed no increase in locomotor activity in response to (1S, 3R)-ACPD or AMPH when these were microinjected into the NAcc. The two groups of rats were indistinguishable when tested following NAcc saline. These findings suggest that, as with AMPH, enhanced locomotion produced by NAcc mGluR activation is dependent on intact DA neurotransmission in this site.

Dopamine depletion reorganizes projections from the nucleus accumbens and ventral pallidum that mediate opioid-induced motor activity

Motor activity elicited pharmacologically from the nucleus accumbens by the mu-opioid receptor agonist D-Ala-Tyr-Gly-NMePhe-Gly-OH (DAMGO) is augmented in rats sustaining dopamine depletions. GABAergic projections from the nucleus accumbens to ventral pallidum and ventral tegmental area (VTA) are involved because stimulation of GABAB receptors in the VTA (by baclofen) or GABAA receptors in the ventral pallidum (by muscimol) inhibit the motor response induced by the microinjection of DAMGO into the nucleus accumbens. The present study was done to determine which of these projections is mediating the augmented DAMGO-induced motor activity that follows 6-hydroxydopamine lesions of the nucleus accumbens. The inhibition of DAMGO-induced activation by pallidal injections of muscimol was markedly attenuated in lesioned animals, whereas the inhibition by VTA injections with baclofen was greatly enhanced. A similar switch in emphasis from pallidal to mesencephalic efferents was not observed for dopamine-induced motor activity, because muscimol microinjections inhibited the response elicited by dopamine microinjection into the nucleus accumbens in all subjects. The stimulation of mu-opioid receptors in the ventral pallidum also elicits motor activation, and this is blocked by baclofen microinjection into the VTA. However, after dopamine depletion in the nucleus accumbens, baclofen in the VTA was ineffective in blocking the motor response by DAMGO in the ventral pallidum. These data reveal that dopamine depletion in the nucleus accumbens produces a lesion-induced plasticity that alters the effect of mu-opioid receptor stimulation on efferent projections from the nucleus accumbens and ventral pallidum.

GABAergic modulation of ventral pallidal dopamine release studied by in vivo microdialysis in the freely moving rat

The mesopallidal dopamine system, which originates from the ventral tegmental area and projects to the ventral pallidum (VP), has been recently shown to play an important role in self-stimulation reward and cocaine reward. VP also receives a GABAergic projection from nucleus accumbens (NAS). The aim of the present study was to examine the involvement of this GABAergic projection in the modulation of VP dopamine release. Both the GABAA antagonist picrotoxin (2-200 microM) and the GABAB antagonist phaclofen (20-2,000 microM), perfused locally, dose-responsively increased VP extracellular dopamine 2-2.5-fold. Cocaine (10 microM) produced a 6.5-fold increase of VP dopamine. Neither picrotoxin (200 microM), phaclofen (2,000 microM), nor GABA (20-2,000 microM) altered the response of VP dopamine to locally applied cocaine. GBR 12909 (0.5 microM), a selective dopamine uptake blocker, induced a 3.5-fold increase of VP dopamine. The increase of VP dopamine in response to GBR 12909 was further augmented to 8.5-fold of baseline when picrotoxin (200 microM) was added to the perfusate. The data from the present study demonstrate that the GABAergic NAS-VP projection can modulate ventral pallidal dopamine release. However, the effect of GABA on the mesopallidal dopamine system's response to locally applied cocaine may be complicated by actions of cocaine other than dopamine uptake inhibition.

Different neural mechanisms underlie dizocilpine maleate- and dopamine agonist-induced locomotor activity

This study evaluated and compared the role of mesoaccumbens dopamine and the ventral pallidal region in the locomotor stimulatory action of the non-competitive N-methyl-D-aspartate antagonist dizocilpine maleate and dopamine agonists. Intra-accumbens injections of both amphetamine (1, 5 and 25 nmol) and dizocilpine maleate (1, 5, 25 and 50 nmol) induced a dose-dependent increase in locomotor activity. The N-methyl-D-aspartate antagonist was somewhat less effective than amphetamine. 6-Hydroxydopamine dopamine-depleting lesions of the nucleus accumbens completely blocked locomotor stimulation induced by focal administrations of amphetamine (5 nmol), but were ineffective in altering the actions of dizocilpine maleate (50 nmol). Ibotenic acid lesions of the ventral pallidal region and muscimol injections into this area also prevented the stimulatory effects of systemic amphetamine (1 mg/kg), while having no effect on the locomotor-activating actions of systemic dizocilpine maleate (0.3 mg/kg). Microdialysis studies revealed that systemically administered apomorphine (2 mg/kg) significantly decreased extracellular GABA in the pallidum, which was accompanied by substantial increases in locomotor output. Systemically administered dizocilpine maleate (0.3 mg/kg), on the other hand, also increased locomotor activity without having any effect on pallidal GABA. These data, taken together, indicate that while the locomotor effects of dopamine agonists are dependent upon intact mesoaccumbens dopamine and involve GABAergic efferents from the nucleus accumbens to the ventral pallidum, dizocilpine maleate's stimulatory actions are independent of such mechanisms.

Clonazepam prevents the development of sensitization to methamphetamine

The GABA-benzodiazepine neurotransmission has been implicated in various forms of plasticity such as kindling and learning. The present study examined the effects of clonazepam (CZP), a GABA-benzodiazepine agonist, on the development of behavioral sensitization to methamphetamine (MA). Rats treated with MA (1 mg/kg, S.C.) for 10 days displayed significantly enhanced motor activity when tested with MA (1 mg/kg) after a 7-8-day withdrawal, indicating the development of behavioral sensitization. Pretreatment with CZP (0.5 and 2.0 mg/kg) prior to MA administration prevented the development of the phenomenon. Rats treated with CZP alone showed no difference in the motor activity compared to those treated with saline. These results suggest that stimulation of GABA-benzodiazepine receptors plays a role in the development of behavioral sensitization.

Brain microdialysis of GABA and glutamate: what does it signify?

Microdialysis has become a frequently used method to study extracellular levels of GABA and glutamate in the central nervous system. However, the fact that the major part of GABA and glutamate as measured by microdialysis does not fulfill the classical criteria for exocytotic release questions the vesicular origin of the amino acids in dialysates. Glial metabolism or reversal of the (re)uptake sites has been suggested to be responsible for the pool of nonexocytotically released amino-acid transmitters that seem to predominate over the neuronal exocytotic pool. The origin of extracellular GABA and glutamate levels and, as a consequence, the implications of changes in these levels upon manipulations are therefore obscure. This review critically analyzes what microdialysis data signify, i.e., whether amino-acid neurotransmitters sampled by microdialysis represent synaptic release, carrier-mediated release, or glial metabolism. The basal levels of GABA and glutamate are virtually tetrodotoxin- and calcium-independent. Given the fact that evidence for nonexocytotic release mediated by reversal of the uptake sites as a release mechanism relevant for normal neurotransmission is so far limited to conditions of "excessive stimulation," basal levels most likely reflect a nonneuronal pool of amino acids. Extracellular GABA and glutamate concentrations can be enhanced by a wide variety of pharmacological and physiological manipulations. However, it is presently impossible to ascertain that the stimulated GABA and glutamate in dialysates are of neuronal origin. On the other hand, under certain stimulatory conditions, increases in amino-acid transmitters can be obtained in the presence of tetrodotoxin, again suggesting that aspecific factors not directly related to neurotransmission underlie these changes in extracellular levels. It is concluded that synaptic transmission of GABA and glutamate is strictly compartmentalized and as a result, these amino acids can hardly leak out of the synaptic cleft and reach the extracellular space where the dialysis probe samples.

Dissociation of locomotor and conditioned place preference responses following manipulation of GABA-A and AMPA receptors in ventral pallidum

1. This study examined the roles of GABAergic and glutamatergic neurotransmission in ventral pallidum (VP) in conditioned place preference and locomotor activity. 2. Picrotoxin (0.1 microgram), a GABA antagonist, and (+/-)alpha-amino-3-hydroxy-5-methylisoxazole-4-propionate (AMPA; 0.14 microgram), a non-NMDA glutamatergic agonist, were injected bilaterally into VP through implanted cannulae. 3. Both drugs produced a robust increase in locomotion, but neither produced conditioned place preference. 4. These results suggest a dissociation of locomotor activity and reward at the level of ventral pallidum. In addition, it was argued that the GABAergic projection from nucleus accumbens to ventral pallidum may not be involved in the processing of reward initiated from dopaminergic activation in nucleus accumbens.

The role of mesoaccumbens--pallidal circuitry in novelty-induced behavioral activation

When exposed to an environment for the first time, rats express greater behavioral activation than rats which were previously habituated to that environment. The circuit containing the ventral tegmental area, nucleus accumbens and ventral pallidum is required for the expression of locomotor activity elicited by amphetamine-like psychostimulants. It was hypothesized that this circuit is necessary for the expression of novelty-induced motor activity. Dopamine is a neurotransmitter in the projection from the ventral tegmental area to the nucleus accumbens, while GABA is contained in the projections from the nucleus accumbens to the ventral pallidum and from the ventral pallidum back to the ventral tegmental area. Prior to exposing rats to a novel or habituated environment, they received a microinjection of either saline vehicle or one of the following drugs: fluphenazine (dopamine antagonist) into the nucleus accumbens, muscimol (GABAA agonist) into the ventral pallidum, or baclofen GABAB agonist) into the ventral tegmental area. Each of these pretreatments prevented novelty-induced motor activation without suppressing the activity of habituated animals. In contrast, when these microinjections were made into adjacent motor nuclei of the basal ganglia, including fluphenazine into the striatum, muscimol into the globus pallidus and baclofen into the substantia nigra, they were ineffective in blocking novelty-induced motor activity. These data indicate that the integrity of the circuit that contains the ventral tegmental area, nucleus accumbens and ventral pallidum is required for the manifestation of novelty-induced motor activity.

Antagonistic interaction between adenosine A2A receptors and dopamine D2 receptors in the ventral striopallidal system. Implications for the treatment of schizophrenia

Recent studies have shown the existence of a specific antagonistic interaction between adenosine A2a receptors and dopamine D2 receptors in the brain. This A2a-D2 interaction seems to be essential for the behavioural effects of adenosine agonists and antagonists, like caffeine. In the present study quantitative receptor autoradiography and brain microdialysis were combined to demonstrate a powerful antagonistic A2a-D2 interaction in the ventral striopallidal system. In the presence of the A2a agonist (2-p-carboxyethyl)phenylamino-5'-N carboxamidoadenosine, dopamine exhibited a lower efficacy in displacing the radiolabelled D2 receptor antagonist [125I]iodosulpiride from the rat ventral striatum, specially in the nucleus accumbens. A tonic dopaminergic modulation of the striopallidal neurons from the ventral striopallidal system was demonstrated by a dual-probe approach, by infusing selective dopamine agonists and antagonists in the nucleus and by measuring dopamine extracellular levels in the nucleus accumbens and GABA extracellular levels in the nucleus accumbens and in the ipsilateral ventral pallidum. The infusion of (2-p-carboxyethyl)phenylamino-5'-N-carboxamidoadenosine in the nucleus accumbens induced the same postsynaptic changes as the D2 antagonist raclopride, i.e. an increase in pallidal GABA extracellular levels, without changing those levels in the nucleus accumbens. Furthermore, the coinfusion in the nucleus accumbens of low concentrations of (2-p-carboxyethyl) phenylamino-5'-N-carboxamido-adenosine and raclopride, which were ineffective when administered alone, induced a significant increase in pallidal gamma-aminobutyric acids extracellular levels. These results suggest that A2a agonists, alone or in combination with D2 antagonists, could be advantageous antischizophrenic drugs, as blockage of D2 receptors in the ventral striopallidal system appears to be associated with the antipsychotic activity of neuroleptics but not with their extrapyramidal motor-side effects.

Neuropharmacology of the nucleus accumbens: systemic morphine effects on single-unit responses evoked by ventral pallidum stimulation

Extracellular recordings of neurons in the nucleus accumbens septi of anesthetized rats have previously shown systemic opiates to have mixed effects on rates of unit activity. However, these effects become more predictable as nucleus accumbens septi neurons are functionally categorized by their responses to afferent stimulation. In the present study, the effects of systemic opiates on individual nucleus accumbens septi neurons categorized by their response patterns to ventral pallidum stimulation were examined. Across all nucleus accumbens septi units tested, these experiments showed that morphine either inhibited (42%, n = 91), excited (15%, n = 32) or had no effect (43%, n = 93) on these unit responses. Further experiments were conducted in which nucleus accumbens septi neurons were categorized on the basis of their response patterns to concurrent fimbria and ventral pallidum stimulation. In these studies, if the neuron was orthodromically evoked to respond by both fimbria stimulation and ventral pallidum stimulation, the neurons' responses to ventral pallidum stimulation (but not their fimbria-evoked responses) were consistently inhibited by morphine. In contrast, nucleus accumbens septi unit responses that were orthodromically activated by ventral pallidum stimulation but unaffected by fimbria stimulation were consistently unaffected by morphine. The major observation of this work is that the effect of systemically administered morphine on individual nucleus accumbens septi neurons can be predicted by that neuron's evoked responses to stimulation of different efferent and afferent circuits. Since these studies involve systemic administration of morphine, the results do not elucidate site of action.(ABSTRACT TRUNCATED AT 250 WORDS)