Is dopamine a neurotransmitter within the ventral pallidum/substantia innominata?

Effects of D2 dopamine receptor activation in the ventral pallidum on sensory gating and food-motivated learning in control and schizophrenia model (Wisket) rats

Dopamine D₂ receptors (D₂Rs) of the ventral pallidum (VP) play important role in motivational and learning processes, however, their potential role in triggering schizophrenic symptoms has not been investigated, yet. In the present experiments the effects of locally administered D₂R agonist quinpirole were investigated on behavioral parameters related to sensorimotor gating, motor activity and food-motivated labyrinth learning. Two weeks after bilateral implantation of microcannulae into the VP, the acute (30 min) and delayed (3, 21 and 24 h) effects of quinpirole microinjection (1 μg/0.4 μL at both sides) were investigated in Wistar and schizophrenia model (Wisket substrain) rats in prepulse inhibition (PPI) and the reward-based Ambitus tests. Quinpirole administration did not modify the impaired sensorimotor gating in Wisket rats, but it led to significant deficit in Wistar animals. Regarding the locomotor activity in the Ambitus test, no effects of quinpirole were detected in either groups at the investigated time points. In contrast, quinpirole resulted in decreased exploratory and food-collecting activities in Wistar rats with 21 and 24 h delay. Though, impaired food-related motivation could be observed in Wisket rats, but quinpirole treatment did not result in further deterioration. In summary, our results showed that the VP D₂R activation in Wistar rats induces symptoms similar to those observed in schizophrenia model Wisket rats. These data suggest that Wisket rats might have significant alterations in the functional activity of VP, which might be due to its enhanced dopaminergic activity.

Preproenkephalin-expressing ventral pallidal neurons control inhibitory avoidance learning

The ventral pallidum (VP) is a critical component of the basal ganglia neurocircuitry regulating learning and decision making; however, its precise role in controlling associative learning of environmental stimuli conditioned to appetitive or aversive outcomes is still unclear. Here, we investigated the expression of preproenkephalin, a polypeptide hormone previously shown to be expressed in nucleus accumbens neurons controlling aversive learning, within GABAergic and glutamatergic VP neurons. Next, we explored the behavioral consequences of chemicogenetic inhibition or excitation of preproenkephalin-expressing VP neurons on associative learning of reward- or aversion-paired stimuli in autoshaping and inhibitory avoidance tasks, respectively. We reveal for the first time that preproenkephalin is expressed predominantly in GABAergic rather than glutamatergic VP neurons, and that excitation of these preproenkephalin-expressing VP neurons was sufficient to impair inhibitory avoidance learning. These findings indicate the necessity for inhibition of preproenkephalin-expressing VP neurons for avoidance learning, and suggest these neurons as a potential therapeutic target for psychiatric disorders associated with maladaptive aversive learning.

The role of the human globus pallidus in Huntington's disease

Huntington's disease (HD) is characterized by pronounced pathology of the basal ganglia, with numerous studies documenting the pattern of striatal neurodegeneration in the human brain. However, a principle target of striatal outflow, the globus pallidus (GP), has received limited attention in comparison, despite being a core component of the basal ganglia. The external segment (GPe) is a major output of the dorsal striatum, connecting widely to other basal ganglia nuclei via the indirect motor pathway. The internal segment (GPi) is a final output station of both the direct and indirect motor pathways of the basal ganglia. The ventral pallidum (VP), in contrast, is a primary output of the limbic ventral striatum. Currently, there is a lack of consensus in the literature regarding the extent of GPe and GPi neurodegeneration in HD, with a conflict between pallidal neurons being preserved, and pallidal neurons being lost. In addition, no current evidence considers the fate of the VP in HD, despite it being a key structure involved in reward and motivation. Understanding the involvement of these structures in HD will help to determine their involvement in basal ganglia pathway dysfunction in the disease. A clear understanding of the impact of striatal projection loss on the main neurons that receive striatal input, the pallidal neurons, will aid in the understanding of disease pathogenesis. In addition, a clearer picture of pallidal involvement in HD may contribute to providing a morphological basis to the considerable variability in the types of motor, behavioral, and cognitive symptoms in HD. This review aims to highlight the importance of the globus pallidus, a critical component of the cortical-basal ganglia circuits, and its role in the pathogenesis of HD. This review also summarizes the current literature relating to human studies of the globus pallidus in HD.

Slow phasic and tonic activity of ventral pallidal neurons during cocaine self-administration

Ventral pallidal (VP) neurons exhibit rapid phasic firing patterns within seconds of cocaine-reinforced responses. The present investigation examined whether VP neurons exhibited firing rate changes: (1) over minutes during the inter-infusion interval (slow phasic patterns) and/or (2) over the course of the several-hour self-administration session (tonic firing patterns) relative to pre-session firing. Approximately three-quarters (43/54) of VP neurons exhibited slow phasic firing patterns. The most common pattern was a post-infusion decrease in firing followed by a progressive reversal of firing over minutes (51.16%; 22/43). Early reversals were predominantly observed anteriorly whereas progressive and late reversals were observed more posteriorly. Approximately half (51.85%; 28/54) of the neurons exhibited tonic firing patterns consisting of at least a two-fold change in firing. Most cells decreased firing during drug loading, remained low over self-administration maintenance, and reversed following lever removal. Over a whole experiment (tonic) timescale, the majority of neurons exhibited an inverse relationship between calculated drug level and firing rates during loading and post-self-administration behaviors. Fewer neurons exhibited an inverse relationship of calculated drug level and tonic firing rate during self-administration maintenance but, among those that did, nearly all were progressive reversal neurons. The present results show that, similar to its main afferent the nucleus accumbens, VP exhibits both slow phasic and tonic firing patterns during cocaine self-administration. Given that VP neurons are principally GABAergic, the predominant slow phasic decrease and tonic decrease firing patterns within the VP may indicate a disinhibitory influence upon its thalamocortical, mesolimbic, and nigrostriatal targets during cocaine self-administration.

The ventral pallidum is critically involved in the development and expression of morphine-induced sensitization

Repeated, intermittent exposure to drugs of abuse results in response enhancements to subsequent drug treatments, a phenomenon referred to as sensitization. As persistent neuronal sensitization may contribute to the long-lasting consequences of drug abuse, characterizing the neuroanatomical substrates of sensitization is providing insights into addiction. It is known that the ventral tegmental area (VTA) is necessary for induction, and expression involves the nucleus accumbens (NAc). We reveal here that the ventral pallidum (VP), a brain region reciprocally innervated by the VTA and the NAc, is a critical mediator of opiate-induced behavioral sensitization. Blockade of VP mu-opioid receptors (via intra-VP CTOP injections) negated the ability of systemic administration of the opiate, morphine to induce motor sensitization, and for sensitized rats to subsequently express enhanced responding to a morphine challenge. Intra-VP morphine was sufficient to induce motor sensitization, and this sensitization was expressed following 17 days of withdrawal. Rats with a treatment history of intra-VP morphine demonstrated cross-sensitization to a challenge injection of systemically administered morphine. Conversely, repeated systemic treatments of morphine cross-sensitized to an intra-VP morphine challenge. These results indicate that activation of VP mu-opioid receptors is sufficient to evoke behavioral sensitization and that these receptors are necessary for sensitized responding to systemic morphine. The study pioneers the concept that both development and expression of drug-induced sensitization are regulated by the VP. Thus, the VP is likely an important contributor to neuronal adaptations that underlie addiction.

Targeting endogenous mu- and delta-opioid receptor systems for the treatment of drug addiction

Drug addiction is a chronic, relapsing disorder that is characterized by a compulsion to take drug regardless of the adverse consequences that may ensue. Although the involvement of mesoaccumbal dopamine neurons in the initiation of drug abuse is well-established, neuroadaptations within the limbic cortical- striatopallidal circuit that occur as a consequence of repeated drug use are thought to lead to the behavioral dysregulation that characterizes addiction. Opioid receptors and their endogenous ligands are enriched in brain regions comprising this system and are, thus, strategically located to modulate neurotransmission therein. This article will review data suggesting an important role of mu-opioid receptor (MOPr) and delta opioid receptor (DOPr) systems in mediating the rewarding effects of several classes of abused drugs and that aberrant activity of these opioid systems may not only contribute to the behavioral dysregulation that characterizes addiction but to individual differences in addiction vulnerability.

Ventral pallidum roles in reward and motivation

In recent years the ventral pallidum has become a focus of great research interest as a mechanism of reward and incentive motivation. As a major output for limbic signals, the ventral pallidum was once associated primarily with motor functions rather than regarded as a reward structure in its own right. However, ample evidence now suggests that ventral pallidum function is a major mechanism of reward in the brain. We review data indicating that (1) an intact ventral pallidum is necessary for normal reward and motivation, (2) stimulated activation of ventral pallidum is sufficient to cause reward and motivation enhancements, and (3) activation patterns in ventral pallidum neurons specifically encode reward and motivation signals via phasic bursts of excitation to incentive and hedonic stimuli. We conclude that the ventral pallidum may serve as an important 'limbic final common pathway' for mesocorticolimbic processing of many rewards.

Fos expression following activation of the ventral pallidum in normal rats and in a model of Parkinson's Disease: implications for limbic system and basal ganglia interactions

The circuit-related consequences of activating the ventral pallidum (VP) are not well known, and lacking in particular is how these effects are altered in various neuropathological states. To help to address these paucities, this study investigated the brain regions affected by VP activation by quantifying neurons that stain for Fos-like immunoreactivity (ir). Fos-ir was assessed after intra-pallidal injections of the excitatory amino acid agonist, NMDA, or the GABA(A) antagonist, bicuculline in normal rats and in those rendered Parkinsonian-like by lesioning dopaminergic neurons with the neurotoxin, 6-OHDA. We hypothesized that activation of the VP will alter the activity state of brain regions associated with both the basal ganglia and limbic system, and that this influence would be modified in the Parkinsonian state. Blocking tonically activated GABA(A) receptors with bicuculline (50 ng/0.5 microl) elevated Fos-ir in the VP to 423% above the contralateral, vehicle-injected side. Likewise, intra-VP NMDA (0.23 microg or 0.45 microg/0.5 microl), dose-dependently increased the number of pallidal neurons expressing Fos-ir by 224 and 526%, respectively. At higher NMDA doses, the density of Fos-ir neurons was not elevated above control levels. This inverted U-shaped profile was mirrored by a VP output structure, the medial subthalamic nucleus (mSTN). The mSTN showed a 289% increase in Fos-ir neurons with intra-VP injections of 0.45 microg NMDA, and this response was halved following intra-VP injections of 0.9 microg NMDA. Of the 12 other brain regions measured, three showed VP NMDA-induced enhancements in Fos-ir: the frontal cortex, entopeduncular nucleus and substantia nigra pars reticulata, all regions associated with the basal ganglia. In a second study, we evaluated the NMDA activation profile in a rat model of Parkinson's Disease (PD) which was created by a unilateral injection of 6-OHDA into the rostral substantia nigra pars compacta. Comparisons of responses to intra-VP NMDA between the hemispheres ipsilateral and contralateral to the lesion revealed that Fos-ir cells in the pedunculopontine nucleus was reduced by 62%, whereas Fos-ir for the basolateral amygdala and STN was reduced by 32 and 42%, respectively. These findings support the concept that the VP can influence both the basal ganglia and the limbic system, and that that the nature of this influence is modified in an animal model of PD. As the VP regulates motivation and cognition, adaptations in this system may contribute to the mood and mnemonic disorders that can accompany PD.

Nullifying drug-induced sensitization: behavioral and electrophysiological evaluations of dopaminergic and serotonergic ligands in methamphetamine-sensitized rats

Repeated exposure to methamphetamine produces a persistent enhancement of the acute motor effects of the drug, commonly referred to as behavioral sensitization. Behavioral sensitization involves monoaminergic projections to several forebrain nuclei. We recently revealed that the ventral pallidum (VP) may also be involved. In this study, we sought to establish if treatments with antagonists or partial agonists to monoaminergic receptors could "reverse" methamphetamine-induced behavioral and VP neuronal sensitization. Behavioral sensitization was obtained in rats with five once-daily s.c. injections of 2.5mg/kg methamphetamine, an effect that persisted for at least 60 days. After the development of sensitization, 15 once-daily treatments of mirtazapine (a 5-HT(2/3), alpha(2) and H(1) antagonist), SKF38393 (D(1) partial agonist) or SCH23390 (dopamine D(1) antagonist) nullified indices of motor sensitization as assessed by measuring the motoric response to an acute methamphetamine challenge 30 days after the fifth repeated methamphetamine treatment. VP neurons recorded in vivo from methamphetamine-sensitized rats at the 30-day withdrawal time also showed a robust downward shift in the excitatory responses observed to an acute i.v. methamphetamine challenge in non-sensitized rats. This decreased excitatory effect was reversed by mirtazapine, but not by other antagonists that were tested. These data suggest a potential therapeutic benefit for mirtazapine in the treatment of methamphetamine addiction, and point to a possible role for the VP in the sensitization process to methamphetamine.

Dopamine receptor regulation of ethanol intake and extracellular dopamine levels in the ventral pallidum of alcohol preferring (P) rats

Sufficient evidence exists for the inclusion of the ventral pallidum (VP) into the category of a dopaminoceptive brain region. The effects of inhibiting dopamine D(1)- or D(2)-like receptors in the VP on (a) ethanol intake and (b) extracellular levels of dopamine, were investigated in the alcohol-preferring (P) rat. The D(1)-like antagonist, SCH-23390, and the D(2)-like antagonist, sulpiride (0.25-2 microg/0.5 microl) were bilaterally injected into the VP and ethanol (15%, v/v) intake was assessed in a 1 h limited access paradigm. The results indicate that microinjections of sulpiride significantly increased ethanol consumption (65% increase at the 2.0 microg dose). Whereas the D(1) antagonists SCH-23390 tended to decrease ethanol intake, the effect was not statistically significant. In a separate group of rats, reverse microdialysis of sulpiride and SCH-23390 (10-200 microM) were conducted in the VP of P rats. Local perfusion of only the 200 microM sulpiride dose significantly increased the extracellular levels of dopamine (maximal increase: 250% of baseline). On the other hand, local perfusion of SCH-23390 (10-200 microM) dose dependently increased the extracellular levels of dopamine 180-640% of baseline. Overall, the results of this study suggest that (a) tonic activation of D(2) postsynaptic receptors in VP imposes a limit on ethanol intake in the P rat; (b) there are few D(2) autoreceptors functioning in the VP; (c) there is tonic D(1)-like receptor mediated inhibitory feedback regulation of VP-dopamine release.

Cross-sensitization to morphine in cocaine-sensitized rats: behavioral assessments correlate with enhanced responding of ventral pallidal neurons to morphine and glutamate, with diminished effects of GABA

Common neurobiological substrates contribute to the progressively increased behavioral effects (i.e., sensitization) that occur with repeated intermittent treatments of cocaine and morphine. Consequently, repeated exposure to cocaine can augment responding to morphine (termed cross-sensitization). Drug-induced sensitization in rats may model aspects of the dysfunction in motivation that are imposed by addiction. The ventral pallidum (VP) is involved in motivated behaviors and its function is altered by acute administration of cocaine and morphine, but the effects of repeated drug exposure remain unknown. Targeting this paucity, the present study evaluated electrophysiological changes in the VP of rats exposed to five once-daily cocaine treatments (15 mg/kg i.p.). This regimen also induced behavioral-sensitization that was expressed 3 days later when the rats received either an acute injection of cocaine (15 mg/kg i.p.) or morphine (10 mg/kg i.p.). VP neurons recorded in vivo 3 days after the repeated cocaine treatment regimen demonstrated increased excitatory responding to microiontophoretic applications of morphine and glutamate. The maximal effect (E(max)) was increased without altering potency, suggesting a change in the functional efficacy of the respective receptor systems. This did not represent a potentiation in transmission in general, for the effects of GABA were diminished. The results provide the first evidence for cellular adaptation in the VP after a sensitizing drug treatment paradigm and reveal that cross-sensitization of drug-induced behaviors temporally correlates with changes in VP neuronal responding. These findings advance an emerging theme that alterations in the VP may contribute to the increased motivation for drug seeking that occurs in drug-withdrawn addicts.

Mu and kappa opioid agonists modulate ventral tegmental area input to the ventral pallidum

The ventral pallidum (VP) is situated at the convergence of midbrain dopamine and accumbal opioid efferent projections. Using in vivo electrophysiological procedures in chloral hydrate-anaesthetized rats, we examined whether discrete application of mu- [D-Ala2,N-Me-Phe4,Gly-ol5 (DAMGO)] or kappa- (U50488) opioid receptor agonists could alter VP responses to electrical stimulation of ventral tegmental area. Rate suppressions occurred frequently following ventral tegmental area stimulation. Consistent with an involvement of dopamine in this effect, none of the 12 spontaneously active ventral pallidal neurons recorded in rats that had monoamines depleted by reserpine responded to electrical stimulation of ventral tegmental area. Moreover, in intact rats, the dopamine antagonist flupenthixol attenuated evoked suppression in 100% of the neurons tested; however, the GABAA antagonist bicuculline was able to slightly attenuate the response in 50% of the neurons tested. These observations concur with our previous studies in indicating that ventral tegmental area stimulation releases dopamine (and sometimes GABA) onto ventral pallidal neurons. Both DAMGO and U50488 decreased the inhibitory effects of ventral tegmental area stimulation. These effects on the endogenously released transmitter differed from those seen with exogenously applied dopamine, for DAMGO did not alter the efficacy or potency of microiontophoretically applied dopamine. Taken together, these observations suggest that the interaction between DAMGO and dopamine does not occur at a site that is immediately postsynaptic to the dopaminergic input within the VP, but rather that opioid modulation involves mechanisms governing presynaptically released dopamine. These modulatory processes would enable ventral pallidal opioids to gate the influence of ventral tegmental area dopamine transmission on limbic system outputs at the level of the VP.

Dopamine D1/D2 agonists injected into nucleus accumbens and ventral pallidum differentially affect locomotor activity depending on site

Ventral pallidal dopamine has been recently shown to play an important role in psychostimulant reward and locomotor activation. The aim of the present study was to compare the roles of ventral pallidal D1 and D2 receptors in evoking locomotor activity with those in the nucleus accumbens. The D1 agonist SKF 38393 and the D2 agonist quinpirole hydrochloride (0.3-3 microg/ 0.5 microl) were bilaterally injected into ventral pallidum or nucleus accumbens through pre-implanted cannulae. In the ventral pallidum, 0.3-1 microg SKF 38393 increased locomotor activity while 3 microg had no effect; 3 microg quinpirole suppressed locomotion while 0.3-1 microg had no effect. Locomotor activity induced by an equigram (0.3 microg) mixture of SKF 38393 and quinpirole, while significantly higher than that induced by 0.3 microg quinpirole was not significantly higher than that induced by 0.3 microg SKF 38393 alone. At the 3 microg dose, SKF 38393 injections into anterior ventral pallidum increased activity; injections into posterior ventral pallidum decreased activity. In the nucleus accumbens, 0.3-3 microg SKF 38393 dramatically increased locomotor activity while quinpirole moderately increased locomotion. In the group that had previously received the full quinpirole dose range, injection of the equigram (0.3 microg) mixture of SKF 38393 and quinpirole induced locomotor activation which was higher than that induced by either drug alone or by the addition of the effect of each drug alone, i.e. synergy occurred. Moreover, rats that had previously received SKF 38393 developed a sensitized locomotor response to subsequent SKF 38393, quinpirole or the mixture of these two drugs. The difference in locomotor response to dopamine agonists between the ventral pallidum and nucleus accumbens is consistent with electrophysiological evidence collected at these two sites. These findings suggest that, unlike the nucleus accumbens, where D1 and D2 receptor activation may facilitate each other to induce a synergistic effect on locomotor activity, ventral pallidal D1 and D2 receptors may be located on different neurons and coupled with different, if not opposite, behavioral output.

Ventral pallidal injections of a mu antagonist block the development of behavioral sensitization to systemic morphine

Acute activation of opioid receptors in the ventral pallidum increases motor behaviors in rats. The present study was designed to investigate the possibility that the ventral pallidum influences motor responses induced by chronic opiate treatments and to examine the receptors that may be involved in such an effect. For five consecutive days, ambulations were quantified after rats received once-daily intraperitoneal (i.p.) injections of morphine (10 mg/kg) or saline following bilateral intra-ventral pallidal injections of either saline (0.5 microl/hemisphere), the mu antagonist CTOP (2. 1 microg/0.5microl/hemisphere), or the D1 antagonist SCH23390 (0.25 microg/0.5microl/hemisphere). Behavioral sensitization to an acute morphine challenge (10 mg/kg i.p.) was assessed 72 h after terminating the repeated treatment regimen. Rats who repeatedly received the intra-ventral pallidal saline + i.p. morphine exhibited increases in ambulations during the chronic treatment protocol and this effect was greatly enhanced (i.e., sensitized) following the post withdrawal acute morphine challenge. Rats repeatedly treated with intra-ventral pallidal CTOP + i.p. morphine did not display a motor response either during the chronic treatment regime or to the acute morphine challenge; an effect not seen when CTOP was injected into brain structures located dorsal to the ventral pallidum. The rats repeatedly treated with intra-ventral pallidal injections of SCH23390 + i.p. morphine demonstrated a motor response during the chronic protocol but the magnitude of this response was not significantly enhanced by the acute morphine challenge. These results demonstrate that: 1) mu opioid and D1-like dopamine receptors in the ventral pallidum influence the increase in locomotion that occurs during repeated morphine treatments; and 2) mu opioid (but not D1) receptors in the ventral pallidum are important in the postwithdrawal sensitized response to morphine. Such observations indicate that the ventral pallidum plays a critical role in morphine-induced behavioral sensitization.

Opioid modulation of ventral pallidal inputs

While the ventral pallidum (VP) is known to be important in relaying information between the nucleus accumbens and target structures, it has become clear that substantial information processing occurs within the VP. We evaluated the possibility that opioid modulation of other transmitters contained in VP afferents is involved in this process. Initially, we demonstrated that opioids hyperpolarized VP neurons in vitro and suppressed spontaneous firing in vivo. The ability of opioids to modulate other transmitters was determined using microiontophoretically applied ligands and extracellular recordings of VP neurons from chloral hydrate-anesthetized rats. With neurons that responded to iontophoresed opioid agonists, the ejection current was reduced to a level that was below that necessary to alter spontaneous firing. This "subthreshold" current was used to determine the ability of mu opioid receptor (microR) agonists to alter VP responses to endogenous (released by electrical activation of afferents) and exogenous (iontophoretically applied) transmitters. microR agonists decreased the variability and enhanced the acuity (e.g., "signal-to-noise" relationship) of VP responses to activation of glutamatergic inputs from the prefrontal cortex and amygdala. By contrast, microR agonists attenuated both the slow excitatory responses to substance P and GABA-induced inhibitions that resulted from activating the nucleus accumbens. Subthreshold opioids also attenuated inhibitory responses to stimulating midbrain dopaminergic cells. These results suggest that a consequence of opioid transmission in the VP is to negate the influence of some afferents (e.g., midbrain dopamine and accumbal GABA and substance P) while selectively potentiating the efficacy of others (e.g., cortical and amygdaloid glutamate). Interpreted in the context of opiate abuse, microR opioids in the VP may serve to diminish the influence of reinforcement (ventral tegmental area and nucleus accumbens) in the transduction of cognition (prefrontal cortex) and affect (amygdala) into behavior. This may contribute to drug craving that occurs even in the absence of reward.

A circuitry model of the expression of behavioral sensitization to amphetamine-like psychostimulants

Repeated exposure to psychostimulants such as cocaine and amphetamine produces behavioral sensitization, which is characterized by an augmented locomotor response to a subsequent psychostimulant challenge injection. Experimentation focused on the neural underpinnings of behavioral sensitization has progressed from a singular focus on dopamine transmission in the nucleus accumbens and striatum to the study of cellular and molecular mechanisms that occur throughout the neural circuitry in which the mesocorticolimbic dopamine projections are embedded. This research effort has yielded a conglomerate of data that has resisted simple interpretations, primarily because no single neuronal effect is likely to be responsible for the expression of behavioral sensitization. The present review examines the literature and critically evaluates the extent to which the neural consequences of repeated psychostimulant administration are associated with the expression of behavioral sensitization. The neural alterations found to contribute to the long-term expression of behavioral sensitization are centered in a collection of interconnected limbic nuclei, which are termed the 'motive' circuit. This neural circuit is used as a template to organize the relevant biochemical and molecular findings into a model of the expression of behavioral sensitization.

GABA- and glutamate-evoked responses in the rat ventral pallidum are modulated by dopamine

Microiontophoresis was used to investigate the influence of dopamine on GABA- and glutamate-induced responses from ventral pallidal neurons recorded extracellularly in chloral hydrate-anaesthetized rats. Modulation was determined by comparing dopamine-induced alterations in amino acid-induced activity ('signal') with dopamine-induced effects on spontaneous firing ('noise'). A dopamine ejection current-response curve was generated to determine the current levels that did not alter spontaneous firing ('subthreshold') and those that produced approximately 50% of the maximal dopamine-induced response (ECur50). Co-iontophoresis of dopamine with GABA generally diminished the inhibitory influence of GABA on pallidal neuron firing; 70% of neurons tested with ECur50 dopamine demonstrated a decrease in the signal-to-noise ratio whereas 10% displayed an increase. At subthreshold dopamine ejection currents, 59% of neurons responded with a decrease and 18% responded with an increase in the GABA signal-to-noise ratio. When ECur50 dopamine was co-iontophoresed with glutamate, 84% of the neurons displayed a decrease in the signal-to-noise ratio for glutamate-evoked excitations whereas 11% demonstrated an increase. Subthreshold dopamine ejection currents decreased the signal-to-noise ratio in 62% of the ventral pallidal neurons excited by glutamate and increased the ratio in 23%. These data illustrate that dopamine substantially alters GABA- and glutamate-evoked responses even at ejection currents that are below those necessary to change spontaneous firing. Thus, it appears that neuromodulation is an important means by which dopamine influences ventral pallidal neuronal activity.

6-Hydroxydopamine lesion of ventral pallidum blocks acquisition of place preference conditioning to cocaine

In parallel with nucleus accumbens (NAS), ventral pallidum (VP) also receives a dopaminergic projection from the ventral tegmental area (VTA). The present study examined the involvement of this mesopallidal dopaminergic system in the action of cocaine. In the first experiment, the effect of cocaine injections on VP dopamine was examined by microdialysis. Intraperitoneal (i.p.) injections of cocaine 5-20 mg/kg dose-dependently increased the extracellular dopamine level in VP 2.5-4.5-fold. In addition, intra-VP perfusion of 20 microM cocaine induced a 12-fold increase of dopamine locally. The second experiment examined the role of VP dopamine in cocaine-induced conditioned place preference (CPP) and locomotor activation. Rats received bilateral intra-VP injections of 3-4 microg 6-OHDA or ascorbic acid vehicle in 0.5 microl volume. Tissue assays indicated that the 6-OHDA-lesioned rats had significantly lowered dopamine concentration in VP, but not in NAS or striatum. As a group, 6-OHDA lesions blocked the development of CPP to 5 mg/kg cocaine but not to 10 mg/kg cocaine. However, rats with more than 60% depletion in VP dopamine did not develop CPP to cocaine at either dose. Preference for the cocaine-paired side correlated significantly with dopamine concentration in VP, but not in NAS or striatum. It was concluded that VP dopamine may play a critical role in the initial rewarding effect of cocaine. 6-OHDA lesions also blocked locomotor activation induced by 5 mg/kg cocaine but had no effect on 10 mg/kg cocaine-induced locomotion. Dopamine concentration in VP did not correlate with the locomotor activation response to cocaine at either dose. These findings further establish the involvement of the mesopallidal dopaminergic system in the action of cocaine.

Modulation of cognitive processes by transsynaptic activation of the basal forebrain

Each of the neurotransmitter-specific afferents to the basal forebrain (BF) carry different types of information which converge to regulate the activity of cholinergic projections to telencephalic areas. Brainstem monoaminergic and cholinergic inputs are critical for context-dependent arousal. GABAergic afferents are gated by a variety of ascending and descending systems, and in addition provide an intrinsic control of BF output excitability. Corticofugal glutamatergic inputs represent reciprocal connections from sites to which BF afferents project, and carry information about the current level of cortical processing intensity and capacity. Peptidergic inputs arise from hypothalamic sources and locally modulate BF output as a function of motivational and homeostatic processes. The significance of these afferent systems can be studied by examining the behavioral consequences of infusion into the BF of drugs that act on the specific receptor systems. Although traditional analyses suggest that the BF has many behavioral functions that can be subdivided regionally, an analysis of studies employing transsynaptic approaches lead to the conceptualization of the BF as having a uniform function, that of maximizing cortical processing efficiency. The BF is conditionally active during specific episodes of acquisition and processing of behaviorally significant, externally-derived information, and drives cortical targets into a state of readiness by reducing interference and amplifying the processing of relevant stimuli and associations, thus allowing for more efficient processing. This paper describes the transsynaptic approach to studying BF function, reviews the neurobiological and behavioral consequences of altering neurotransmitter-specific inputs to the BF, and explores the functional significance of the BF.

Contribution of the nucleus accumbens to cocaine-induced responses of ventral pallidal neurons

The present study characterized the responses of ventral pallidal (VP) neurons to intravenously (iv) administered cocaine (0.003, 0.01, 0.03, 0.1, 0.3, and 1.0 mg/kg) in chloral hydrate-anesthetized rats. Eighty-four percent (16/19) of the tested neurons displayed rate changes following cocaine administration. Fifty-three percent responded by increasing firing rate, with an EMAX of 217 +/- 26% of basal activity and an ED50 of 0.07 +/- 0.03 mg/kg. Neurons that responded with a rate decrease (26%) had an EMAX of 14.3 +/- 9.0% of basal control and an ED50 of 0.04 +/- 0.02 mg/kg. One neuron (5%) displayed a biphasic response pattern. Haloperidol (0.2 mg/kg) attenuated cocaine-induced effects in 90% of the tested neurons. Given the responsiveness of VP neurons to cocaine, the extensive innervation of the VP by the nucleus accumbens (NAC), and the importance of the NAC in regulating cocaine-induced effects, it is likely that NAC activity may affect VP responses to cocaine. To test this possibility, the influence of NAC on cocaine-induced VP activity was evaluated. Unilateral inactivation of the NAC with microinjections of procaine (40 mu g/2 mu l/2 min) did not alter the proportion of VP neurons responsive to subsequent systemic administration of cocaine (0.1, 1.0 mg/kg iv) or the EMAX for those neurons showing a rate decrease. However, for the population of neurons showing a cocaine-induced rate increase, intra-NAC procaine significantly enhanced EMAX to 392 +/- 74% of control. These data suggest that the ability of VP neurons to respond to iv cocaine is independent of the NAC. However, the magnitude of the cocaine-induced effect appears to be dependent on NAC influences.

Electrophysiological verification of the presence of D1 and D2 dopamine receptors within the ventral pallidum

The ventral pallidum is a basal forebrain region recently shown to receive dopaminergic projections from the midbrain. Binding sites for the D1 and D2 dopamine receptor families have been identified within the ventral pallidum, yet the consequences of activating these receptors have not been studied. Thus, to characterize the physiological pharmacology of D1 and D2 receptor subtypes for the ventral pallidum, extracellular single-neuron recording and microiontophoretic techniques were used in chloral hydrate-anesthetized rats. Half of the 93 ventral pallidal neurons tested were sensitive to iontophoresis of dopamine (DA), and both rate increases and decreases were observed. Co-iontophoresis of either the D1 antagonist SCH23390, or the D2 antagonist sulpiride, generally attenuated the DA-induced rate changes. Like DA, about half of the ventral pallidal neurons tested were sensitive to the D1 agonist, SKF38393. Yet in contrast to DA, rate suppression was observed almost exclusively, and the magnitude of this decrease was greater than that produced by DA. SKF38393-induced suppressions were antagonized by SCH23390, but not by sulpiride, demonstrating the specificity of the D1 agonist. Most of the neurons tested were not affected by quinpirole, but when responsive to the D2 agonist, rate increases were observed most often. The increases were antagonized by the D2 antagonist sulpiride, but not SCH23390, demonstrating that this response resulted from an activation of D2 receptors. These results support binding studies demonstrating that both D1 and D2 receptors are present in the ventral pallidum, and reveal that the independent activation of each of these is sufficient to alter neuronal activity.

Prefrontal cortical dopamine systems and the elaboration of functional corticostriatal circuits: implications for schizophrenia and Parkinson's disease

The dopaminergic innervation of the prefrontal cortex is able to transsynaptically regulate the activity of subcortical dopamine innervations. Disruption of the prefrontal cortical DA innervation results in the enhanced biochemical responsiveness of the dopamine innervation of the nucleus accumbens. We present recent data indicating that distinct prefrontal cortical dopamine innervations can be functionally dissociated on the basis of responsiveness to stress. The ventral striatal projection target (nucleus accumbens shell) of the prefrontal cortical region that is stress sensitive is also responsive to stress. In this manner interconnected cortico-striato-pallido-mesencephalic loops can be defined on the basis of the biochemical responsive of local dopamine systems to stress and on the basis of responsiveness to antipsychotic drugs. These data suggest the functional derangement of a distinct corticofugal loops in schizophrenia and in certain aspects of Parkinson's disease.

Systemic and microiontophoretic administration of morphine differentially effect ventral pallidum/substantia innominata neuronal activity

In vivo electrophysiological recording techniques were employed to examine responses of ventral pallidum/substantia innominata (VP/SI) neurons to systemic and local administration of morphine. Using a cumulative dosing protocol, intravenous administration (0.1-30 mg/kg i.v.) produced a suppression of firing in 82% of neurons tested. The suppression was dose-related and blocked by the opioid antagonist, naloxone. In contrast, microiontophoretic applications of morphine resulted in current-related suppression (32% of neurons tested) or excitation (26%). Concurrent application of naloxone attenuated or blocked both effects of local morphine application. It was demonstrated that acute tolerance did not develop with repeated morphine exposures following either systemic or local administration. The present findings establish the sensitivity of VP/SI neurons to morphine and provide functional relevance at the level of a single neuron for opioid peptides and their receptors in this region. As reported for most other opioid-receptive brain areas, neuronal rate suppression was the predominate response observed, and it is proposed that excitations to iontophoresed morphine reflect a disinhibitory phenomenon. The differential morphine-induced rate changes, and number of responding neurons, observed with systemic vs. iontophoretic morphine administration suggest that extra-VP/SI regions that also are opioid sensitive can subsequently direct neuronal responsiveness to opioids within the VP/SI.

Contribution of the amygdala and nucleus accumbens to ventral pallidal responses to dopamine agonists

Neurons recorded from ventral pallidum/substantia innominata (VP) of the basal forebrain respond to dopaminergic agonists that activate either the D1 or D2 the receptor subtype. Major afferent systems to the VP originate within amygdaloid nuclei (AMN) and the nucleus accumbens (NA). Since both the AMN and the NA are dopaminoceptive, the present study sought to analyze the contribution of these afferent systems to VP responses to dopaminergic agonists. Single VP neurons were electrophysiologically recorded in vivo from chloral hydrate-anesthetized rats, and the following determinations were made. 1) Effects of pharmacologic inactivation of an afferent system were assessed by monitoring VP neurons during intracerebral microinjections of the local anesthetic procaine, administered directly into either the AMN or the NA. 2) With procaine-induced VP rate changes used to indicate an afferent influence on the recorded neuron, VP responses to apomorphine (an agonist that acts at D1 and D2 receptor subtypes), SKF38393 (a D1 agonist), or quinpirole (a D2 agonist) were determined and compared with responses in rats not receiving the procaine pretreatment. Following pharmacologic inactivation of either the AMN or the NA, approximately 80% of the VP neurons monitored demonstrated rate changes, illustrating that spontaneous neuronal firing in the Vp is dependent on tonically input systems. Following afferent cessation, responses to apomorphine and quinpirole remained intact, suggesting that the AMN or NA is not necessary for VP responding to the systemic administration of dopaminergic agonists that act at D2 receptors. In contrast, the number of neurons that responded to SKF38393 was diminished follow intra-AMN (but not intra-NA) procaine. This suggests that D1-induced VP responses are mediated, at least in part, via the AMN.