Projection neurons of the nucleus accumbens: an intracellular labeling study

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.

Third pathway in the cortico-basal ganglia loop: Neurokinin B-producing striatal neurons modulate cortical activity via striato-innominato-cortical projection

In the cortico-basal ganglia loop, striatal regions serve as 'entrances' to the basal ganglia, receiving massive inputs from the cerebral cortex and sending 'direct' and 'indirect' pathways to the output nuclei of the basal ganglia. However, we have recently identified a new striatofugal subgroup which produces neurokinin B (NKB). Although NKB-producing neurons constitute a minority of striatal neurons, this subgroup is distinguished by the unique distribution and chemical characteristics. NKB-producing striatal neurons are distributed in association with mu-opioid receptor localization, and rarely express DARPP32, which is produced by the major striatofugal neurons and coupled with dopaminergic signaling. Further interestingly NKB-producing striatal neurons send axons to basal forebrain regions, but not to the main target regions of striatal outflow, pallidal or mesencephalic regions. In the basal forebrain, some GABAergic inhibitory neurons express NK3 receptor, selective receptor for NKB, and directly send axons to the cerebral cortex. The NK3-expressing neurons show different electrical properties from cholinergic basal forebrain neurons, and display facilitatory responses to stimulation of NK3 receptor. These findings strongly suggest that NKB-producing striatal neurons and NK3-expressing basal forebrain neurons constitute a third pathway which bypasses the common output nuclei of the basal ganglia, and more directly control or modulate cortical activity.

Typical and atypical antipsychotic drugs target dopamine and cyclic AMP-regulated phosphoprotein, 32 kDa and neurotensin-containing neurons, but not GABAergic interneurons in the shell of nucleus accumbens of ventral striatum

Specific neurons in the brain are the primary targets of the action of antipsychotic drugs. Identification and characterization of the nature of these neurons are important for understanding how antipsychotic drugs produce their effects. In previous studies GABAergic/dynorphinergic neurons were identified as a principal cell target of antipsychotic drugs in the shell of nucleus accumbens. In the present study, we further characterized which subpopulations of GABAergic neurons in this area respond after acute administration of antipsychotic drugs. Rats were treated with the typical antipsychotic haloperidol, or the prototype atypical antipsychotic clozapine and killed two hours after treatment. In appropriate sections of brain, double immunofluorescence labeling was performed with antibodies directed against markers specific to candidate cell types and Fos-like proteins (a marker to identify drug-induced cell activation). We reported here that haloperidol- and clozapine-activated neurons showed the following features: 1) approximately 54-57% of them express dopamine and cyclic AMP-regulated phosphoprotein, 32 kDa (a marker for GABAergic medium spiny projection neurons), 2) they appear rarely to be GABAergic interneurons, marked by the calcium binding proteins, parvalbumin, calretinin or calbindin-D28K, 3) about 84-86% of them express the neuropeptide neurotensin (a neurotransmitter most often associated with projection neurons in the site tested). The results suggest that most of the antipsychotic drug-activated neurons in the shell of nucleus accumbens are likely to be neurotensin containing projection neurons.

Dopamine excites nucleus accumbens neurons through the differential modulation of glutamate and GABA release

Afferent activity into the nucleus accumbens (NAc) occurs in bursts of action potentials. However, it is unclear how synapses in this nucleus respond to such bursts, or how these responses are altered by dopamine (DA). I examined the effects of DA on excitatory and inhibitory responses to trains of stimuli in rat NAc slices. Both EPSCs and IPSCs showed use-dependent depression during trains. Although DA inhibited both glutamate and GABA release in the NAc, it differentially inhibited release during trains. The inhibition of IPSCs persisted throughout the train of stimuli, whereas the inhibition of EPSCs progressively diminished. This differential modulation may be explained by a calcium-dependent change in the recovery from depression at the GABA synapses, where DA acts by decreasing Ca2+ entry. Thus, at later stages of sustained stimulation, DA preferentially inhibits GABA release, producing a net excitatory effect during bursts suggesting a mechanism for enhancing the contrast between competing inputs into the NAc, as well as for affecting long-term plasticity in this structure.

The role of mesolimbic dopamine in the development and maintenance of ethanol reinforcement

The neurobiological processes by which ethanol seeking and consumption are established and maintained are thought to involve areas of the brain that mediate motivated behavior, such as the mesolimbic dopamine system. The mesolimbic dopamine system is comprised of cells that originate in the ventral tegmental area (VTA) and project to several forebrain regions, including a prominent terminal area, the nucleus accumbens (NAcc). The NAcc has been subdivided into core and shell subregions. Both areas receive converging excitatory input from the cortex and amygdala and dopamine input from the VTA, with the accumbal medium spiny neuron situated to integrate the signals. Although forced ethanol administration enhances dopamine activity in the NAcc, conclusions regarding the role of mesolimbic dopamine in ethanol reinforcement cannot be made from these experiments. Behavioral experiments consistently show that pharmacological manipulations of the dopamine transmission in the NAcc alter responding for ethanol, although ethanol reinforcement is maintained after lesions of the accumbal dopamine system. Additionally, extracellular dopamine increases in the NAcc during operant self-administration of ethanol, which is consistent with a role of dopamine in ethanol reinforcement. Behavioral studies that distinguish appetitive responding from ethanol consumption show that dopamine is important in ethanol-seeking behavior, whereas neurochemical studies suggest that accumbal dopamine is also important during ethanol consumption before pharmacological effects occur. Cellular studies suggest that ethanol alters synaptic plasticity in the mesolimbic system, possibly through dopaminergic mechanisms, and this may underlie the development of ethanol reinforcement. Thus, anatomical, pharmacological, neurochemical, cellular, and behavioral studies are more clearly defining the role of mesolimbic dopamine in ethanol reinforcement.

Electrophysiological characteristic of corticoaccumbens synapses in rat mesolimbic system reconstructed using organotypic slice cultures

The nucleus accumbens (NAc) is a component of the mesolimbic system involved in drug dependence. Activity of nucleus accumbens neurons is modulated by glutamatergic afferents from the prefrontal cortex and by dopaminergic afferents from the ventral tegmental area (VTA). In the present study, we reconstructed the mesolimbic system using organotypic slice cultures and examined the effects of dopaminergic agents on synaptic activity in the prefrontal cortex-nucleus accumbens synapses. A slice of each of the prefrontal cortex, nucleus accumbens and ventral tegmental area in newborn rat, was arranged on a multi-electrode dish (MED) filled with culture medium so that they contacted each other, termed a 'triple culture'. Extracellular recording using microelectrodes on the multi-electrode dish showed that a single electrical stimulation of the prefrontal cortex slice evoked field excitatory postsynaptic potential, and that population spikes occurred spontaneously in the nucleus accumbens area of the triple culture. The amplitude of evoked field excitatory postsynaptic potentials and the frequency of spontaneous population spikes were decreased by glutamatergic antagonists, D(-)-2-amino-5-phosphonovaleric acid and 6-cyano-7-nitroquinoxaline-2,3-dione. The D1-like receptor agonist SKF38393, but not the D2-like receptor agonist quinpirole, reduced both the amplitude of field excitatory postsynaptic potential and frequency of spontaneous population spikes. Cocaine depressed field excitatory postsynaptic potential and this depression was reversed by D1-like receptor antagonist SCH23390, but not by D2-like receptor antagonist sulpiride. These results suggest that evoked field excitatory postsynaptic potentials and spontaneous population spikes were driven by glutamatergic neurons and were subject to exogenous and endogenous dopaminergic modulation in the triple culture that was similar to that shown in in vivo.

Intravenous heroin self-administration decreases GABA efflux in the ventral pallidum: an in vivo microdialysis study in rats

Several lines of evidence suggest that opiate-induced disinhibition of the ventral pallidum participates in the mediation of opiate reward, though direct in vivo evidence to support this hypothesis has been lacking. The present experiment tested this hypothesis by investigating alterations in ventral pallidal amino acid efflux using in vivo microdialysis during ongoing intravenous heroin self-administration in rats. Concentrations of the inhibitory amino acid GABA in ventral pallidal dialysates were significantly reduced within the first 10 min of heroin self-administration (0.02 mg per infusion; FR-1), and remained approximately 65% of presession baseline levels for the remainder of the 3-h self-administration session. Dialysate glutamate levels were unaltered during the first hour of heroin intake but significantly increased to a stable level of approximately 120% presession values during the subsequent 2 h of self-administration. Thus, heroin self-administration is associated with both decreased GABA efflux and a late phase increase in glutamate efflux in the ventral pallidum. These observations are consistent with the hypothesis that heroin self-administration results in a disinhibition and/or excitation of the ventral pallidum.

Cue-Evoked Firing of Nucleus Accumbens Neurons Encodes Motivational Significance During a Discriminative Stimulus Task

The nucleus accumbens (NAc) has long been thought of as a limbic-motor interface. Despite behavioral and anatomical evidence in favor of this idea, little is known about how NAc neurons encode information about motivationally relevant environmental cues and use this information to affect motor action. We therefore investigated the firing of these neurons during the performance of a discriminative stimulus (DS) task using simultaneous multiple single-unit recordings in rats. In this task, two stimuli are randomly presented to the animal: a DS, which signals the availability of a sucrose reward contingent on an operant response, and a similar but nonrewarded stimulus (NS). Subpopulations of NAc neurons increased or decreased their firing in association with several distinct components of the task. In this paper, we investigate cue- and operant-responsive neurons. Neurons excited and inhibited by cues showed larger firing changes in response to the DS than the NS and larger changes when the animal made an operant response to the cue than when the animal failed to respond. Excitations during operant responding were not modulated by the information contained by the cue, whereas inhibitions during operant responding were somewhat larger if the operant response occurred during the DS and somewhat smaller if they occurred in the absence of a cue. These results are consistent with the hypothesis that the firing of subpopulations of NAc neurons encode both the predictive value of environmental stimuli and the specific motor behaviors required to respond to them.

Direct Physiological Evidence for Synaptic Connectivity Between Medium-Sized Spiny Neurons in Rat Nucleus Accumbens In Situ

Dual whole cell patch-clamp recordings in rat nucleus accumbens, the main component of the ventral striatum, were made to assess the presence of synaptic interconnections between medium-sized spiny neurons, a group of GABAergic and peptidergic neurons that constitute the principal cells of the striatum. Neurons were stained with biocytin for subsequent morphological analysis. Electrical activity of cells was recorded in current- and voltage-clamp mode; the characteristics of medium-sized spiny neurons were confirmed by electrophysiological and morphological properties. Thirteen of 38 medium-sized spiny neuron pairs (34%) showed a synaptic connection. In these pairs, suprathreshold stimulation with current injection evoked a train of action potentials in the presynaptic cell, which in turn elicited depolarizing postsynaptic potentials (dPSPs) in the postsynaptic cell. Twelve of these 13 pairs were connected unilaterally. The onset latency of the postsynaptic response was 1.7 ± 0.7 ms. dPSPs were blocked by 12.5 μM bicuculline, suggesting they were mediated by GABAA receptors. A linear fit of the current-voltage relationship of GABAergic currents crossed the voltage axis near the value of -20 mV, in agreement with the Cl- equilibrium potential predicted from the composition of the artificial cerebrospinal fluid and pipette medium. No evidence for electrotonic coupling was found. Paired-pulse facilitation and depression were induced when the amplitude of the first IPSC of a pair was relatively small and large, respectively. No clear dependence of paired-pulse facilitation or depression was found on the width of the spike interval, which ranged between 100 and 380 ms. Conversely, 1- to 2-s trains of dPSPs showed marked frequency facilitation at low presynaptic frequencies, but frequency depression at high firing rates. These data show that intra-accumbens synaptic communication between medium-sized spiny neurons exists, is mediated by GABAA receptors, and exhibits spike train-dependent short-term dynamics.

Prefrontal lesion reverses abnormal mesoaccumbens response in an animal model of schizophrenia

BACKGROUND

A neonatal hippocampal lesion induces postpubertal behavioral alterations resembling phenomena observed in schizophrenia. We have recently reported that nucleus accumbens neurons exhibit altered response to ventral tegmental area activation, but only when animals with this lesion reach adulthood. Because a prefrontal cortical lesion eliminates postpubertal abnormal behaviors in these animals, we investigated whether altered accumbens responses were reversed with this manipulation.

METHODS

In vivo intracellular recordings were conducted in accumbens neurons in rats that had received neonatal hippocampal lesions combined with either adult prefrontal cortical lesion or sham treatment. Accumbens response to mesolimbic pathway activation was recorded in these animals.

RESULTS

Accumbens neurons from animals with a neonatal hippocampal lesion and an adult prefrontal sham operation still showed altered accumbens response to mesolimbic stimulation. On the other hand, most animals with combined neonatal hippocampal and adult prefrontal lesions exhibited responses similar to those of naïve animals.

CONCLUSIONS

This result suggests that abnormal behaviors in these animals might be related to excessive prefrontal drive of accumbens neurons upon dopamine activation.

Dopamine receptor subtypes selectively modulate excitatory afferents from the hippocampus and amygdala to rat nucleus accumbens neurons

The nucleus accumbens (NAc) receives excitatory afferents from several cortical and limbic regions and dense dopaminergic inputs from the ventral tegmental area. We examined the effects of dopamine (DA) D1 and D2 selective drugs on the responses evoked in the NAc shell neurons recorded in vitro by stimulation of hippocampal and amygdaloid afferents. Activation of hippocampal and amygdaloid afferents induced excitatory postsynaptic responses that were depressed by bath application of DA in most of the cells recorded. The DA effect was substantially blocked by the D1 receptor antagonist SCH 23390, but not by the D2 receptor antagonist eticlopride. Moreover, the D1 receptor agonist SKF 38393, but not the D2 receptor agonist quinpirole, mimicked the effects of DA, although a small population of neurons exhibited a D1-mediated facilitation of the EPSP amplitude following fornix stimulation. These data demonstrate a DA receptor subtype-specific modulation of glutamatergic inputs to the NAc, with D1 agonists attenuating amygdaloid inputs, whereas hippocampal-evoked responses were either depressed or potentiated by D1 stimulation. Such facilitation or attenuation of hippocampal afferents against a background of suppression of other afferents would permit the hippocampus to have a dominant influence over behavior during periods of exploration.

Kappa opioid receptor activation in the nucleus accumbens inhibits glutamate and GABA release through different mechanisms

Through their actions in the nucleus accumbens (NAc), kappa opioid (KOP) receptors and their endogenous ligand, dynorphin, modify behaviors associated with the administration of drugs of abuse and are regulated by exposure to such drugs. Despite their demonstrated behavioral significance, the synaptic actions of KOP receptor ligands in the NAc are not clearly understood. Using whole-cell voltage-clamp recordings of NAc medium spiny neurons, we have found that, in addition to suppressing glutamate release, the KOP receptor agonist also inhibits GABA release. Interestingly, the mechanism of inhibition of the release of glutamate differs from that controlling GABA. reduces the frequency of Ca(2+)-independent miniature excitatory postsynaptic currents, but not miniature inhibitory postsynaptic currents. Furthermore, while the inhibition of GABAergic transmission is blocked by the N-type Ca(2+) channel blocker omega-CgTx, the inhibition of excitatory glutamatergic transmission by is unaffected by N-type Ca(2+) channel blockade. These results indicate that KOP receptor activation inhibits GABA release by reducing Ca(2+) influx, but inhibits glutamate release at a step downstream of Ca(2+) entry.

Preprodynorphin-, preproenkephalin-, preprotachykinin A- and preprotachykinin B-immunoreactive neurons in the accumbens nucleus and olfactory tubercle: double-immunofluorescence analysis

Preprodynorphin (PPD), preproenkephalin (PPE) and preprotachykinins A (PPTA) and B (PPTB) are known to be expressed by neostriatal projection neurons. In the present study, we investigated the distributions and colocalizations of immunoreactivities for those prepropeptides in the ventral striatum, such as the accumbens nucleus (Acb) and olfactory tubercle (OT). Antibodies raised against C-terminal portions of the prepropeptides labeled cell bodies of neurons with diameters of 8-15 microm. PPD-, PPE- and PPTA-immunoreactive neurons were distributed throughout the Acb and concentrated in the dense cell layer of the OT. PPTB-immunoreactive neurons were observed to form cell clusters, which were localized in mu-opioid receptor-immunoreactive patchy regions in the Acb, but were very rarely found in the dense cell layer of the OT. Double-immunofluorescence analysis revealed that PPD, PPE and PPTB immunoreactivities were shown in 69%, 19% and 14% of PPTA-immunoreactive neurons, respectively, in the Acb core region, and in 92%, 7% and 25% of PPTA-immunoreactive neurons, respectively, in the Acb shell region. In the olfactory bulb, 51%, 19% and 3% of PPTA-immunoreactive neurons showed PPD, PPE and PPTB immunoreactivities, respectively. PPD and PPE immunoreactivities were rarely coexpressed in single neurons of all striatal regions. The present results indicated that, although PPTA and PPE were occasionally coexpressed in single neurons of the ventral striatum, the segregated expression of PPD and PPE in the ventral striatum was similar to that in the dorsal striatum. The clustered localization of PPTB-expressing neurons in the Acb and near absence of PPTB-expressing neurons in the dense cell layer of the OT suggests that neurokinin B is a key substance in differentiating between the ventral and dorsal striatal regions.

Network synchrony in the nucleus accumbens in vivo

Nucleus accumbens neurons show membrane potential fluctuations between a very negative resting membrane potential and periodical plateau depolarizations. Because action potential firing occurs only during the depolarized state, the control of transitions between states is important for information processing within this region, with an impact on accumbens-related behaviors. It has been proposed that ensembles of active neurons in the nucleus accumbens could be based on a population of cells depolarizing simultaneously into the UP state. In this study, in vivo intracellular recordings from accumbens neurons were performed simultaneously with local field potential recordings to examine whether the nucleus accumbens can exhibit synchronization of membrane potential states in a population of neurons. These simultaneous recordings indicated that local field potential shifts occurred synchronously with transitions to the UP state. Furthermore, manipulations that evoked prolonged plateau depolarizations also evoked field potentials of similar duration. Such signals likely occurred because of simultaneous membrane potential changes in a population of neurons. Together with our previous studies, these results suggest that membrane potential states in the nucleus accumbens can be synchronized by synaptic inputs from the hippocampus.

Dopamine receptor functions: lessons from knockout mice [corrected]

In the past few years, a number of laboratories have used gene targeting via homologous recombination to generate mice deficient for key molecules involved in dopaminergic (DAergic) transmission. This tremendous effort has resulted in the successful generation and characterization of mice deficient for the neurotransmitter DA, the main terminator of DAergic neurotransmission (the DA transporter), and all five subtypes of DA receptors. This review summarizes the results from studies of the various DA receptor knockout mice and of mice deficient in proteins that mediate DA receptor signaling. It focuses on a comparison of the locomotor phenotypes and responses to drugs of abuse (psychostimulants), and reviews the results of anatomic studies examining the morphological and neurochemical differentiation of the striatum in these mutants. Moreover, an overview of recently published results highlighting the physiological relevance of the interaction between different DA receptors and between DA receptors and other neurotransmitter receptors in the modulation of behavioral and molecular responses to DAergic stimulation is presented. Finally, in view of the recently discovered heteroligomeric assemblies of neurotransmitter receptors that involve DA receptor subtypes, the potential value of knockout mice as a tool for testing the in vivo significance of these heteroligomeric receptors is discussed.

Vesicular acetylcholine transporter in the rat nucleus accumbens shell: subcellular distribution and association with mu-opioid receptors

Cholinergic interneurons in the nucleus accumbens shell (AcbSh) are implicated in the reinforcing behaviors that develop in response to opiates active at mu-opioid receptors (MOR). We examined the electron microscopic immunocytochemical localization of the vesicular acetylcholine transporter (VAChT) and MOR to determine the functional sites for storage and release of acetylcholine (ACh), and potential interactions involving MOR in this region of rat brain. VAChT was primarily localized to membranes of small synaptic vesicles in axon terminals. Less than 10% of the VAChT-labeled terminals were MOR-immunoreactive. In contrast, 35% of the cholinergic terminals formed symmetric or punctate synapses with dendrites showing an extrasynaptic plasmalemmal distribution of MOR. Membranes of tubulovesicles in other selective dendrites were also VAChT-labeled, and almost half of these dendrites displayed plasmalemmal MOR immunoreactivity. The VAChT-labeled dendritic tubulovesicles often apposed unlabeled axon terminals that formed symmetric synapses. Our results indicate that in the AcbSh MOR agonists can modulate the release of ACh from vesicular storage sites in axon terminals as well as in dendrites where the released ACh may serve an autoregulatory function involving inhibitory afferents. These results also suggest, however, that many of the dendrites of spiny projection neurons in the AcbSh are dually influenced by ACh and opiates active at MOR, thus providing a cellular substrate for ACh in the reinforcement of opiates.

Ultrastructural features of the nitric oxide synthase-containing interneurons in the nucleus accumbens and their relationship with tyrosine hydroxylase-containing terminals

The ultrastructural features of neuronal nitric oxide synthase (NOS) -immunoreactive interneurons of rat nucleus accumbens shell and core were studied and compared. The NOS-containing subpopulation displayed characteristics similar to those previously described for nicotinamide adenine dinucleotide phosphate diaphorase-, neuropeptide Y, or somatostatin-containing striatal neurons, but also showed properties not previously associated with them, particularly the formation of both asymmetric and symmetric synaptic junctions. Inputs derived mainly from unlabeled terminals, but some contacts were made by NOS-immunolabeled terminals, by means of asymmetric synapses. Immunopositive endings that formed symmetric synapses were mainly onto dendritic shafts, whereas those that formed asymmetric synapses targeted spine heads. Morphometric analysis revealed that the core and shell NOS-stained neurons had subtly different innervation patterns and that immunostained terminals were significantly larger in the shell. A parallel investigation explored synaptic associations with dopaminergic innervation identified by labeling with an antibody against tyrosine hydroxylase (TH). In both shell and core, TH-positive boutons formed symmetric synapses onto NOS-containing dendrites, and in the core, TH- and NOS-immunolabeled terminals converged on both a single spiny dendrite and a spine. These results suggest that, in the rat nucleus accumbens, NOS-containing neurons may be further partitioned into subtypes, with differing connectivities in shell and core regions. These NOS-containing neurons may be influenced by a dopaminergic input. Recent studies suggest that nitric oxide potentiates dopamine release and the current study identifies the medium-sized, densely spiny neurons as a possible site of such an interaction.

Direct actions of cannabinoids on synaptic transmission in the nucleus accumbens: a comparison with opioids

The nucleus accumbens (NAc) represents a critical site for the rewarding and addictive properties of several classes of abused drugs. The medium spiny GABAergic projection neurons (MSNs) in the NAc receive innervation from intrinsic GABAergic interneurons and glutamatergic innervation from extrinsic sources. Both GABA and glutamate release onto MSNs are inhibited by drugs of abuse, suggesting that this action may contribute to their rewarding properties. To investigate the actions of cannabinoids in the NAc, we performed whole cell recordings from MSNs located in the shell region in rat brain slices. The cannabinoid agonist WIN 55,212-2 (1 microM) had no effect on the resting membrane potential, input resistance, or whole cell conductance, suggesting no direct postsynaptic effects. Evoked glutamatergic excitatory postsynaptic currents (EPSCs) were inhibited to a much greater extent by [Tyr-D-Ala(2), N-CH(3)-Phe(4), Gly-ol-enkephalin] (DAMGO, approximately 35%) than by WIN 55,212-2 (<20%), and an analysis of miniature EPSCs suggested that the effects of DAMGO were presynaptic, whereas those of WIN 55,212-2 were postsynaptic. However, electrically evoked GABAergic inhibitory postsynaptic currents (evIPSCs), were reduced by WIN 55,212-2 in every neuron tested (EC(50) = 123 nM; 60% maximal inhibition), and the inhibition of IPSCs by WIN 55,212-2 was completely antagonized by the CB1 receptor antagonist SR141716A (1 microM). In contrast evIPSCs were inhibited in approximately 50% of MSNs by the mu/delta opioid agonist D-Ala(2)-methionine(2)-enkephalinamide and were completely unaffected by a selective mu-opioid receptor agonist (DAMGO). WIN 55,212-2 also increased paired-pulse facilitation of the evIPSCs and did not alter the amplitudes of tetrodotoxin-resistant miniature IPSCs, suggesting a presynaptic action. Taken together, these data suggest that cannabinoids and opioids differentially modulate inhibitory and excitatory synaptic transmission in the NAc and that the abuse liability of marijuana may be related to the direct actions of cannabinoids in this structure.

Activation of ATP receptor increases the cytosolic Ca(2+) concentration in nucleus accumbens neurons of rat brain

ATP increased the cytosolic Ca(2+) concentration ([Ca](i)) in nucleus accumbens neurons acutely dissociated from rat brain. The ATP response was dependent on external Ca(2+) and Na(+), and was blocked by voltage-dependent Ca(2+) channel blockers. The results suggest that the ATP-induced depolarization increases Ca(2+) influx resulting in the increase in [Ca](i).

Dopaminergic modulation of neuronal excitability in the striatum and nucleus accumbens

The striatum and its ventral extension, the nucleus accumbens, are involved in behaviors as diverse as motor planning, drug seeking, and learning. Invariably, these striatally mediated behaviors depend on intact dopaminergic innervation. However, the mechanisms by which dopamine modulates neuronal function in the striatum and nucleus accumbens have been difficult to elucidate. Recent electrophysiological studies have revealed that dopamine alters both voltage-dependent conductances and synaptic transmission, resulting in state-dependent modulation of target cells. These studies make clear predictions about how dopamine, particularly via D1 receptor activation, should alter the responsiveness of striatal neurons to extrinsic excitatory synaptic activity.

An integrative neuroanatomical perspective on some subcortical substrates of adaptive responding with emphasis on the nucleus accumbens

Neuroanatomical substrates associated in the literature with adaptive responding are discussed, with a focus on the nucleus accumbens. While it is emphasized that the accumbens exhibits multiple levels of complex organization, a fairly complete list of brief descriptions of recent studies devoted specifically to the accumbens shell and core subterritories is presented in tabular format. The distinct patterns of connectivity of the accumbens core and shell and structures related to them by connections are described. Multiple inputs, outputs and abundant reciprocity of connections within the ventral parts of the basal ganglia are emphasized and the implications for "through-put" of impulses is considered. It is noted, at least on neuroanatomical grounds, that there is ample reason to expect feed forward processing from shell and structures with which it is associated to core and structures with which it is associated. Furthermore, the potential for additional feed forward processing involving several forebrain functional anatomical systems, inlcuding the ventral striatopallidum, extended amygdala and magnocellular basal forebrain complex is considered. It is intended that from the considerations recorded here a conceptual framework will begin to emerge that is amenable to further experimental substantiation as regards how multiple basal forebrain systems and the cortices to which they are related by connections work together to fashion a unitary object--the adaptive response.

The synaptic framework for chemical signaling in nucleus accumbens

Our knowledge of the organization of the nucleus accumbens has been greatly advanced in the last two decades, but only now are we beginning to understand the complex neural circuitry that underlies the mix of behaviors attributed to this nucleus. Superimposed on the neurochemically defined territories of the shell and core are four or more conduits for information flow. Each of these behaviorally relevant pathways can be characterized by the spatial distribution of inputs to its central unit: the GABAergic projection neuron, a spiny cell that also contains the opioid peptides, enkephalin or dynorphin. In this review, current models of accumbal circuits will be examined and, with the aid of recent anatomical findings, further extended to shed light on how functionally diverse information is processed in this nucleus. However complex, accumbal wiring is not fixed, and, as we will show, psychostimulants, dopamine-deleting lesions, and chronic blockade of dopaminergic receptors can alter the anatomical substrate, synaptology, and neurotrophic factors that govern circuits through the shell and core.

mu-Opioid receptors are localized to extrasynaptic plasma membranes of GABAergic neurons and their targets in the rat nucleus accumbens

The activation of mu-opioid receptors in the nucleus accumbens (Acb) produces changes in locomotor and rewarding responses that are believed to involve neurons, including local gamma-aminobutyric acid (GABA)ergic neurons. We combined immunogold-silver detection of an antipeptide antiserum against the cloned mu-opioid receptor (MOR) and immunoperoxidase labeling of an antibody against GABA to determine the cellular basis for the proposed opioid modulation of GABAergic neurons in the rat Acb. MOR-like immunoreactivity (MOR-LI) was localized prominently to plasma membranes of neurons having morphological features of both spiny and aspiny cells, many of which contained GABA. Of 351 examples of profiles that contained MOR-LI and GABA labeling, 65% were dendrites. In these dendrites, MOR-LI was seen mainly along extrasynaptic portions of the plasma membrane apposed to unlabeled terminals and/or glial processes. Dually labeled dendrites often received convergent input from GABAergic terminals and/or from unlabeled terminals forming asymmetric excitatory-type synapses. Of all profiles that contained both MOR and GABA immunoreactivity, 28% were axon terminals. MOR-containing GABAergic terminals and terminals separately labeled for MOR or GABA formed synapses with unlabeled dendrites and also with dendrites containing MOR or GABA. Our results indicate that MOR agonists could modulate the activity of GABA neurons in the Acb via receptors located mainly at extrasynaptic sites on dendritic plasma membranes. MOR ligands also could alter the release of GABA onto target dendrites that contain GABA and/or respond to opiate stimulation.

Modulation of synaptic transmission by dopamine and norepinephrine in ventral but not dorsal striatum

Although the ventral striatum (nucleus accumbens; NAc) and dorsal striatum are associated with different behaviors, these structures are anatomically and physiologically similar. In particular, dopaminergic afferents from the midbrain appear to be essential for the normal functioning of both nuclei. Although a number of studies have examined the effects of dopamine on the physiology of NAc or striatal cells, results have varied, and few studies have compared directly the actions of dopamine on both of these nuclei. Here we use slice preparations of the NAc and dorsal striatum to compare how synaptic transmission in these nuclei is modulated by catecholamines. As previously reported, dopamine depressed excitatory postsynaptic potentials (EPSPs) and inhibitory postsynaptic potentials (IPSPs) in the NAc. Surprisingly, however, neither EPSPs nor IPSPs in the dorsal striatum were affected by dopamine. Similarly, norepinephrine depressed excitatory synaptic transmission in the NAc by an alpha-adrenergic receptor-dependent mechanism but was without effect on excitatory transmission in the dorsal striatum. Inhibitory synaptic transmission was not affected by norepinephrine in either structure. These results suggest that the functional roles of dopamine and norepinephrine are not the same in the dorsal striatum and the NAc.

Dopamine depresses excitatory and inhibitory synaptic transmission by distinct mechanisms in the nucleus accumbens

The release of dopamine (DA) in the nucleus accumbens (NAc) is thought to be critical for mediating natural rewards as well as for the reinforcing actions of drugs of abuse. DA and amphetamine depress both excitatory and inhibitory synaptic transmission in the NAc by a presynaptic D1-like DA receptor. However, the mechanisms of depression of excitatory and inhibitory synaptic transmission appear to be different. DA depressed the frequency of spontaneous miniature EPSCs, but the frequency of miniature IPSCs was depressed only when spontaneous release was made dependent on Ca2+ influx through voltage-dependent Ca2+ channels. Furthermore, the K+ channel blocker Ba2+ attenuated the effects of DA on evoked IPSPs, but not on EPSPs. Thus, DA appears to depress inhibitory synaptic transmission in the NAc by reducing Ca2+ influx into the presynaptic terminal, but depresses excitatory transmission by a distinct mechanism that is independent of the entry of Ca2+.

Evidence for a differential cholecystokinin-B and -A receptor regulation of GABA release in the rat nucleus accumbens mediated via dopaminergic and cholinergic mechanisms

In the present study we characterized the cholecystokinin receptor regulation of (i) the dopamine D2 agonist binding sites in striatal sections including the nucleus accumbens and (ii) GABA and dopamine release in the central part of the rat nucleus accumbens, by combining the in vitro filter wipe-off and the in vivo microdialysis techniques. In the binding study we demonstrate that sulphated cholecystokinin octapeptide (1 nM) increased (219 +/- 30%) the KD value of the D2 agonist [3H]N-propylnorapomorphine binding sites in sections from the striatum including the accumbens. This effect was counteracted by the cholecystokinin-B antagonist PD134308 (50 nM). In a parallel study using microdialysis in the central nucleus accumbens, we found that local perfusion with sulphated cholecystokinin octapeptide (1 microM) induced an increase in GABA (135 +/- 7%) and dopamine (146 +/- 8%) release which was unaffected by the cholecystokinin-A antagonist L-364,718 (10 nM). In contrast, when the cholecystokinin-B antagonist PD134308 (10 nM) was co-perfused with the peptide it prevented the increase in dopamine and decreased GABA release (-24 +/- 2%). This reduction was counteracted by the addition to the perfusate medium of the cholecystokinin-A antagonist or the cholinergic muscarinic M2 receptor antagonist AF-DX 116 (0.1 microM). Taken together, these data demonstrate that the facilitation by sulphated cholecystokinin octapeptide of GABA and dopamine release in the central accumbens probably reflects an inhibitory effect of the peptide on both pre- and postsynaptic D2 receptors, mediated via cholecystokinin-B receptor activation. In addition, for the first time we provide evidence for a differential cholecystokinin-A and -B receptor-mediated regulation of GABA transmission in the central accumbens, where the cholecystokinin-B receptor exerts a dominant excitatory influence while the cholecystokinin-A receptor mediates an inhibition of GABA release via a local muscarinic M2 receptor.

Modifications in glutamatergic transmission after dopamine depletion of the nucleus accumbens. A combined in vivo/in vitro electrophysiological study in the rat

The interaction between the glutamatergic and dopaminergic input in the nucleus accumbens was examined by studying the effects of dopamine depletion of the nucleus accumbens on the local field potentials, and the L-glutamate elicited responses of the nucleus accumbens in anaesthetized rats in vivo. A characteristic field potential in the nucleus accumbens is evoked by electrical stimulation of the fornix/fimbria fibres, with a monosynaptic positive peak at 10 ms (P10). Rats were unilaterally injected with 6-hydroxydopamine in the nucleus accumbens. The contralateral accumbens was sham lesioned. The rats were divided into short-term and long-term survival groups of one to two weeks and 24 weeks, respectively. In the short-term group, a striking increase (up to three times) of the amplitude of the P10 components, at the site of the lesion, compared with the sham lesioned contralateral accumbens and untreated rats, was found. The long-term group could still display a slight increase although on average this was not significantly different from controls. In the short-term group, at the centre of the lesion, the paired-pulse facilitation ratio was significantly smaller than at the more ventral, less denervated, border of the accumbens. These differences were no longer visible in the long-term group. Single-unit activity of the accumbens, elicited by the iontophoretical application of L-glutamate showed, in controls, a maximal firing frequency ranging from 5 to 40 Hz (mean 25 Hz), whereas in the short-term group more than 50% of the accumbens neurons fired with higher frequencies, reaching up to 90 Hz (mean 55 Hz). In the long-term group the firing frequency varied from 5 to 60 Hz (mean 41 Hz). No changes in threshold ejection glutamate current were found for both lesioned groups. In control rats the L-glutamate elicited responses of six cells tested could be suppressed by dopamine whereas in lesioned rats three of the six cells tested were unresponsive to dopamine. Intracellular recordings of accumbens cells in slices in 6-hydroxydopamine and sham lesioned rats, showed no significant changes in the intrinsic membrane properties, e.g. resting membrane potential, input resistance, spike threshold, action potential amplitude or duration. We conclude that dopamine denervation leads to an increase of excitability of the principal accumbens neurons. This is reflected by the increase of the firing frequency of these cells and of the amplitude of the evoked field potentials. The former is more likely of postsynaptic origin whereas the latter may also have a presynaptic contribution. These effects cannot be attributed to changes in intrinsic membrane properties of the cells.

Selective sparing of human nucleus accumbens in aging and anoxia

OBJECTIVE

To investigate the effects of aging and anoxia on the nucleus accumbens.

METHODS

The number of neurons in nucleus accumbens and caudate nucleus in 35 patients over 65 and 35 under 65 years, all without neurological or psychiatric disease were counted.

RESULTS

There was no statistically significant difference between the number of neurons in the accumbens in the two groups, but there was a decrease in the number of neurons in the elderly group. There was no reduction in volume of the neuronal nucleoli of the accumbens measured in 12 elderly patients compared to controls. These data suggest a sparing of the accumbens from changes associated with aging. There was relative preservation of the nucleus accumbens in 3 patients with anoxic encephalopathy.

CONCLUSIONS

These results show that accumbens was resistant to both aging and anoxia, the mechanism of which is discussed.

GABAergic axons in the ventral forebrain of the rat: an electron microscopic study

The ventral forebrain, including the ventral striatum, the ventral pallidum and the substantia innominata, is an important region involved in the functions of the basal ganglia and the limbic system, as well as the magnocellular corticopetal neurons of the nucleus basalis of Meynert. Although previous studies have shown that this region is richly innervated by GABAergic fibers, little is known with respect to the relative densities of GABAergic to non-GABAergic axon terminals in this region. To address this issue, we have developed a specific rabbit antiserum to GABA and used a postembedding immunocytochemical reaction to analyse the distribution of GABA-like immunoreactive axon terminals in the rat ventral striatum, ventral pallidum and substantia innominata. Of all axon terminals that form identifiable synapses within single ultrathin sections taken from these regions, 11.6% in the ventral striatum, 85.5% in the ventral pallidum and 64.8% in the substantia innominata were GABAergic. Differences were also found in the distribution patterns of these terminals with respect to the size of their synaptic target dendrites. These findings are consistent with previous findings that a majority of inputs to the ventral striatum are excitatory, and that a majority of inputs to the ventral pallidum are inhibitory. Our results provide a first approximation of the anatomical substrate for the physiology and pharmacology of GABA actions in the ventral forebrain region. These results also show that GABA may play an important role in the substantia innominata, where both the cholinergic and the non-cholinergic magnocellular corticopetal neurons reside within a neuropil innervated by many different non-cholinergic fibers.

Neuropharmacology of the nucleus accumbens: iontophoretic applications of morphine and nicotine have contrasting effects on single-unit responses evoked by ventral pallidal and fimbria stimulation

Extracellular recordings within the nucleus accumbens (NAS) of halothane anesthetized rats have revealed that iontophoretically applied morphine and nicotine have contrasting effects on neuronal responses evoked by fimbria or VP stimulation. Iontophoretically applied morphine inhibited NAS single-unit responses evoked by VP stimulation but did not affect unit responses evoked by fimbria stimulation. In contrast, iontophoretically applied nicotine had no effect on NAS single-unit responses evoked by VP stimulation but inhibited single-unit responses evoked by fimbria stimulation. Spontaneously active NAS units were inhibited by iontophoretically applied morphine but were unaffected by nicotine. In addition, experiments were conducted to determine whether NAS unit responses to electrical stimulation of the VP were likely to involve cell body as opposed to axonal activations. Selective cell body stimulation by glutamate micro-infusions into the VP region excited spontaneously active VP single-units. Concurrently recorded NAS unit responses to electrical stimulation of the VP were also excited. These results are consistent with the idea that NAS evoked responses to VP electrical stimulation involve somal activation. Generally, these results suggest a specific neuropharmacological organization of the NAS. Analysis of the effects of morphine and nicotine on other NAS circuits will establish a systems level understanding of NAS responses to reinforcers.

Neurophysiology and neuropharmacology of projections from entorhinal cortex to striatum in the rat

We studied projections from the entorhinal cortex (Ent) to the striatum in anesthetized rats using extra- and intracellular recording and multibarrel iontophoresis. The majority of recording were from the caudate-putamen (CPu) and core of the nucleus accumbens (AcbC). Electrical stimulation of the Ent evoked synaptic responses in 77% of tests with AcbC neurons and 48% of tests with CPu neurons. In the case of AcbC neurons, 61% of these tests proved to be excitatory and were often followed by inhibitory phases. In contrast to this, only 18% of tests from CPu neurons were excitatory. Intracellular HRP labeling showed that responsive cells were medium spiny neurons. During iontophoretic experiments, application of the glutamatergic AMPA antagonist DNQX could selectively decrease or block excitatory responses. The GABAA antagonist bicuculline methiodide increased cellular firing rates and could reveal excitatory responses, suggesting block of a short-latency, short-duration inhibitory component. Ejection of the GABAB antagonist CGP-35348 could attenuate a later, longer-duration component of inhibition. The results indicate that the Ent excites striatal neurons at least in part by glutamatergic receptors and suggest that this excitation is followed by secondary prolonged GABAergic inhibition.

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)

An investigation of the origin of extracellular GABA in rat nucleus accumbens measured in vivo by microdialysis

GABA transmission in the nucleus accumbens is believed to play a central role in motivational processes and the expression of psychostimulant drug action. Here we report measurements of extracellular GABA in nucleus accumbens of the rat and investigate its origin. Extracellular GABA was detected using microdialysis in combination with a novel HPLC-based assay. In the awake rat, GABA in the microdialysates (1) increased 10-fold following perfusion with 0.5 mM nipecotic acid, a GABA releasing agent and uptake blocker, (2) increased 7-fold following local perfusion with 50 mM KCl, (3) decreased 50% following perfusion with tetrodotoxin, (4) decreased 50% following perfusion with a Ca(2+(-free medium and (5) decreased 40% following perfusion with high (12.5 mM) MgCl. Finally, in the anaesthetized rat, GABA in the microdialysates decreased 50% following i.p. injection of 100 mg/kg 3-mercaptoproprionic acid, a GABA synthesis inhibitor. We conclude that GABA in microdialysates from nucleus accumbens of the rat (awake) responds appropriately to selected pharmacological agents and derives at least in part (50%) from neurones.

Muscarinic modulation of synaptic transmission in slices of the rat ventral striatum is dependent on the frequency of afferent stimulation

Extracellular, intracellular and tight-seal patch-clamp recordings in ventral striatal slices were used to investigate whether the effectiveness of muscarinic neuromodulation of fast synaptic transmission may be dependent on the frequency of afferent stimulation. In all neurons tested, EPSPs were reversibly attenuated by muscarine or carbachol. This action was completely antagonized by atropine or pirenzepine. Several observations indicated a presynaptic site of action. In extracellular recordings, carbachol reduced the monosynaptic population spike but not the non-synaptic compound action potential. The acetylcholinesterase inhibitors eserine and pyridostigmine also induced an atropine-sensitive reduction of the EPSP. When the rate of afferent stimulation was increased, control EPSPs or EPSCs exhibited a decline in peak amplitude until reaching a steady-state value. Muscarinic modulation of steady-state EPSPs/EPSCs was significantly stronger in the range of lower frequencies (0.25-4 Hz) than at higher frequencies (8 and 12 Hz). The GABAA and GABAB-receptor/channel antagonists picrotoxin and 2-hydroxy-saclofen, the opiate receptor antagonist naloxone and atropine failed to alter the shape of the frequency-response curve. These results show that both exogenous and endogenous muscarinic receptor agonists are capable of activating a presynaptic mechanism by which fast excitatory inputs to the ventral striatum are depressed. The depressive effect is clearly stronger at lower rates of afferent stimulation than at high rates. This frequency-dependent attenuation of excitatory synaptic inputs exemplifies a new type of activity-dependent neuromodulation in central neural circuits.

Rostrocaudal subregional differences in the response of enkephalin, dynorphin and substance P synthesis in rat nucleus accumbens to dopamine depletion

Quantitative in situ hybridization histochemistry was used to examine the effects of unilateral 6-hydroxydopamine lesions of the ascending dopaminergic fibres on levels of mRNA encoding the neuropeptides enkephalin, dynorphin and substance P in subregions of the nucleus accumbens. The nucleus accumbens was divided into quadrants and changes in mRNA were measured along the rostrocaudal extent of the nucleus. Two weeks after the lesion an increase was found in enkephalin mRNA in the lesioned side compared to the non-lesioned side, whereas a decrease was observed for dynorphin and substance P mRNA. The changes in mRNA levels differed from quadrant to quadrant and were not uniformly distributed along the rostrocaudal axis. Both types of changes, i.e. increase and decrease, were much higher in rostral parts of the nucleus than in caudal parts, indicating regional differences in the effects of blockade of the dopaminergic neurotransmission. The lesion-induced increases and decreases in mRNA levels occurred in both the shell and the core subregions of the nucleus accumbens and were not specifically related to either of these areas. Factors are discussed that may contribute to the rostrocaudal gradient in the changes of enkephalin, substance P and dynorphin mRNA levels. On the basis of their afferent and efferent connections, the rostral and caudal parts of the nucleus accumbens are considered to be involved in different functions. The present results suggest that dopamine depletion may affect these functions in a differential manner.

Specific neurophysiological effects of systemic nicotine on neurons in the nucleus accumbens

Extracellular recordings of single neurons within the nucleus accumbens (NAS) of halothane-anesthetized rats have revealed that systemic nicotine injections (0.5 and 1.0 mg/kg, s.c.) inhibit the action potentials of normally inactive NAS neurons, evoked by fimbria stimulation (fimbria-driven responses, n = 18). These nicotine inhibitions of fimbria-driven NAS action potentials appear to be centrally mediated because they were reversed by subsequent systemic injections of the centrally acting nicotinic acetylcholine (nAch) antagonist, mecamylamine (1.0 mg/kg, s.c., n = 6) but not by the peripherally acting nAch antagonist, hexamethonium (2.0 mg/kg, s.c., n = 6). Fimbria-driven NAS neurons were also tested with morphine (2.5 mg/kg, s.c.) in some experiments. Consistent with many past observations (Hakan et al., 1989), morphine did not affect these driven neurons. In other experiments, nicotine-induced inhibition of NAS fimbria-driven units was followed by haloperidol (0.5 mg/kg, s.c.), in attempts to reveal the possible role of dopamine in these effects. Haloperidol was successful at reversing nicotine inhibitions in only some cases (n = 2/6). Thus, the role of dopamine in these NAS responses to nicotine remains unclear. In contrast to the fimbria-driven NAS responses, spontaneously active NAS neurons were not affected by nicotine injections yet were subsequently inhibited with systemic morphine. These results suggest a specific neuropharmacological organization in the region of the nucleus accumbens that may relate to the qualitative and subjective differences in the experimental effects of different psychoactive drugs. Iontophoretic studies designed to localize further the site of these nicotine effects on NAS neurons are in progress.

Ultrastructural characteristics of enkephalin-immunoreactive boutons and their postsynaptic targets in the shell and core of the nucleus accumbens of the rat

The present study compared the ultrastructural morphology of enkephalin-immunoreactive boutons and their postsynaptic targets in different territories of the nucleus accumbens in the rat. The synaptic bouton profiles were identified by antibodies directed against [leu5]enkephalin. Ninety-five percent of the synaptic contacts were symmetric in configuration and the remaining 5% were asymmetric. Axosomatic contacts comprised 6% of all enkephalin-immunoreactive junctions and were distributed equally in all parts of the nucleus. Most (76%) synaptic terminals contacted dendrites but they contacted proportionally fewer dendrites in the shell (71%) than in the core (78%). Moreover, enkephalin-immunoreactive synaptic boutons in the shell (19%) and caudal enkephalin-rich areas (17%) of the core contacted twice as many spines than in the remaining parts of the core (8.5%). In the core, long pallidum-like dendrites were occasionally found ensheathed in enkephalin-immunoreactive terminal boutons. We conclude that the differential arrangement of enkephalinergic contacts in the shell and core could have important functional consequences, especially when considered in relation to other known morphological and neurochemical differences between these regions.

Synaptic plasticity in an in vitro slice preparation of the rat nucleus accumbens

Extra- and intracellular recordings in slices were used to examine what types of synaptic plasticity can be found in the core of the nucleus accumbens, and how these forms of plasticity may be modulated by dopamine. Stimulus electrodes were placed at the rostral border of the nucleus accumbens in order to excite primarily infralimbic and prelimbic afferents, as was confirmed by injections of the retrograde tracer fluoro-gold. In extracellular recordings, tetanization induced long-term potentiation (LTP) of the population spike in 20 out of 53 slices. The presynaptic compound action potential did not change following LTP induction. For the intracellularly recorded excitatory postsynaptic potentiation, three types of synaptic plasticity were noted: long-term potentiation (16 out of 54 cells), decremental potentiation (eight cells) and long-term depression (LTD; six cells). No correlation was found between the occurrence of potentiation or depression and various parameters of the tetanic depolarization (e.g. peak voltage, integral under the curve). The N-methyl-D-aspartate receptor antagonist D(-)-2-amino-5-phosphonopentanoic acid (50 microM; D-AP5) reduced, but did not completely prevent, the induction of LTP. The incidence of LTD was not markedly affected by D-AP5. No difference in LTP was found when comparing slices bathed in dopamine (10 microM) and controls. Likewise, slices treated with a mixture of the D1 receptor antagonist Sch 23390 (1 microM) and the D2 antagonist S(-)-sulpiride (1 microM) generated a similar amount of LTP as controls. In conclusion, both LTP and LTD can be induced in a key structure of the limbic-innervated basal ganglia. LTP in the nucleus accumbens strongly depends on N-methyl-D-aspartate receptor activity, but is not significantly affected by dopamine.

Identification of synaptic interactions of intracellularly injected neurons in fixed brain slices by means of dual-label electron microscopy

The injection of the dye Lucifer Yellow (LY) into neurons in slices of fixed brain is used to associate cells displaying a particular dendritic geometry with a specific pattern of neuronal connectivity. In the present report we expand on this technique by combining it at the electron microscopic level with immunocytochemistry and/or degeneration for the study of synaptic relationships. As a model we use the projection neurons of nucleus accumbens. These neurons were retrogradely labeled in vivo with injections or a fluorescent tracer. Fast Blue, into the ventral mesencephalon. Using epifluorescent monitoring, these neurons were located in perfusion-fixed brain slices and intracellularly injected with LY. They were visualized in the light and electron microscope using a peroxidase-antiperoxidase immunocytochemical method. Certain afferent connections of these neurons were identified in the same tissue through the use of either dual-label immunocytochemistry or anterograde degeneration combined with a single-label immunoreaction. In the dual-label procedure, a silver-gold intensification of the diaminobenzidine (DAB) reaction product for the first antigen (LY) was contrasted with a nonintensified reaction product for the second antigen (tyrosine hydroxylase [TH]). Ultrastructurally, metallic gold particles appeared to be dispersed over the immunolabeled perikarya, dendrites, and, occasionally, axonal terminals of LY-injected neurons whereas the flocculent DAB reaction product was present in TH-containing axons and terminals. Following lesions of the ventral subiculum in the hippocampal formation, degenerating axon terminals were detected in nucleus accumbens along with immunoreacted, LY-injected neurons. The techniques outlined in this report should prove invaluable for the study of the synaptic interactions of identified neurons. They can be reliably reproduced with a high yield per experiment.

Electrophysiological evidence for reciprocal connectivity between the nucleus accumbens septi and ventral pallidal region

Responses of nucleus accumbens (NAS) neurons to ventral pallidum (VP) stimulation were examined in anesthetized rats. Results demonstrated: (1) NAS to VP projection neurons reside primarily in the relatively lateral aspects of the NAS, and (2) substantial VP to NAS feedback also exists. These feedback projections are widely distributed throughout the NAS. Moreover, functionally identifiable NAS neuronal subpopulations were revealed by analysis of unit responses to concurrent VP and fimbria stimulation: (1) most, but not all NAS units responded to VP and fimbria stimulation in qualitatively divergent ways; (2) many NAS units demonstrated monosynaptic convergence of fimbria and VP terminations onto individual NAS units; and (3) in other cases, identified NAS-VP projection neurons were also monosynaptically activated by fimbria stimulation.

Differential membrane properties and dopamine effects in the shell and core of the rat nucleus accumbens studied in vitro

Electrophysiological differences between the shell and core of the rat nucleus accumbens were investigated by intracellular recordings from an in vitro slice preparation. The average input resistance of neurons recorded in the shell was larger than in the core. Neurons in the core were characterized by a more negative resting membrane potential than neurons in the shell. Furthermore, bath-applied dopamine attenuated synaptic responses recorded in the shell, but not in the core. Thus, the two main subregions of the nucleus accumbens differ both in basal membrane properties and in dopaminergic modulation of synaptic transmission.

Contribution of NMDA receptors to postsynaptic potentials and paired-pulse facilitation in identified neurons of the rat nucleus accumbens in vitro

The principal aim of this study was to characterize the transmitter mechanisms mediating fast postsynaptic potentials in identified neurons of the rat nucleus accumbens. Using the biocytin-avidin labeling technique, impaled neurons were identified as medium spiny neurons. The basic membrane characteristics of these neurons were determined. Local electrical stimulation or stimulation of the corpus callosum elicited a depolarizing postsynaptic potential consisting of an EPSP often followed by an IPSP. The quisqualate/kainate receptor antagonist 6-cyano-7-nitroquinoxaline-2,3-dione (4 microM) abolished most of the depolarizing postsynaptic potential. The N-methyl-D-aspartate receptor antagonist D(-)-2-amino-5-phosphonopentanoic acid depressed a small part of the decay phase of the depolarizing postsynaptic potential. Paired-pulse facilitation of postsynaptic potentials was found using interstimulus-intervals between 10 and 150 ms. N-methyl-D-aspartate receptors were found to contribute only slightly to the facilitation of the decay phase of the depolarizing postsynaptic potential, but not to its rising phase. This contribution was particularly clear under conditions of reduced GABAA receptor mediated inhibition. The present study indicates that postsynaptic responses of medium spiny neurons in the nucleus accumbens to local stimulation or stimulation of neocortical afferents are primarily mediated by quisqualate/kainate receptors. The contribution of NMDA receptors is normally limited to a portion of the decay phase of these responses, but is enlarged in the absence of GABAergic inhibition and following paired-pulse stimulation.

Locally evoked potentials in slices of the rat nucleus accumbens: NMDA and non-NMDA receptor mediated components and modulation by GABA

In a slice preparation of the rat nucleus accumbens (Acb), local electrical stimulation elicited a field potential composed of two negative peaks, followed by a positive wave. The early negative peak was identified as a non-synaptic compound action potential, the late negative peak as a monosynaptic population spike (PS) and the positive wave as a mixture of an excitatory and an inhibitory postsynaptic potential (PSP). Both the PS and the PSP exhibited a marked degree of paired-pulse facilitation. The quisqualate/kainate receptor antagonist 6-cyano-7-nitroquinoxaline-2,3-dione (CNQX; 2 microM) and the broadly acting glutamate receptor antagonist kynurenic acid (300 microM) reversibly abolished or reduced both the PS and PSP. In contrast, nicotinic, muscarinic and N-methyl-D-aspartate (NMDA) receptor antagonists had no suppressive action. Washout of Mg2+ from the superfusion medium reversibly enhanced and prolonged the PSP and this effect was blocked by the NMDA receptor antagonist D(-)-2-amino-5-phosphonopentanoic acid (D-AP-5). The gamma-aminobutyric acid antagonist picrotoxin (60 microM) enhanced the PS and induced secondary spikes which were superimposed on a prolonged PSP. Most of this prolongation was abolished by D-AP-5. It is concluded that locally evoked synaptic responses in the Acb are mediated by glutamate or aspartate, and that NMDA receptor mediated activity evoked by low frequency stimulation is substantial in Mg2(+)-free medium or during reduced GABAA receptor activity, but not under normal conditions.

In the rat medial nucleus accumbens, hippocampal and catecholaminergic terminals converge on spiny neurons and are in apposition to each other

The nucleus accumbens septi (Acb) represents an interface between limbic and motor systems and a site for modulation of these integrative functions by ascending catecholaminergic, principally dopaminergic, axons. This modulatory regulation is most likely attributed to pre- or postsynaptic associations between limbic telencephalic and brainstem afferents. In the present investigation, we examined the ultrastructure and synaptic associations of hippocampal afferents, as well as their relation to catecholaminergic terminals, in the medial Acb of adult rats. Hippocampal afferents were identified by anterograde transport of wheat germ agglutinin-conjugated horseradish peroxidase (WGA-HRP) injected in the ventral subiculum, and by anterograde degeneration seen 2-3 days following lesion of the fimbria. Specific comparisons between these methods were made (1) to determine whether similar populations of terminals were labeled and (2) to assess the feasibility of combining degeneration with immunoperoxidase labeling for the catecholamine synthesizing enzyme, tyrosine hydroxylase (TH). Hippocampal afferents labeled with HRP were finely myelinated or unmyelinated and gave rise to small terminals (mean diameter 0.58 micron) containing mostly clear, round vesicles. Of the HRP-labeled terminals which made recognizable junctions, 85% (104/122) formed asymmetric synapses with the heads of dendritic spines. The remainder either formed asymmetric axodendritic synapses or symmetric junctions. Degenerating terminals were significantly smaller (mean diameter 0.35 micron) than terminals labeled with HRP. However, these also formed principally asymmetric axospinous synapses (89/102, 87%). Whether identified by HRP transport or anterograde degeneration, the hippocampal afferents comprised approximately 10% of all terminals and 30% of all asymmetric axospinous synapses in the medial Acb. In contrast to hippocampal afferents, TH-labeled terminals formed primarily symmetric contacts with dendritic shafts and the heads and necks of spines. Quantitative analysis of sections containing both anterograde degeneration and TH-immunoreactivity showed that 25% (26/104) of associations formed by degenerating hippocampal terminals involved convergent inputs with TH-labeled terminals on the same postsynaptic structure. These included dual input either to the same spine head or to different parts of the same dendrite. In addition, the plasma membranes of hippocampal and TH-labeled terminals were often directly apposed to each other (10/58, 17% of axo-axonal associations formed by degenerating terminals), without recognizable synaptic specializations.(ABSTRACT TRUNCATED AT 400 WORDS)

Hippocampal fibers make synaptic contacts with glutamate decarboxylase-immunoreactive neurons in the rat nucleus accumbens

Axons arising in the hippocampal formation form asymmetric synapses with glutamate decarboxylase-immunoreactive neurons in nucleus accumbens. The postsynaptic targets included many spines, and less frequently dendritic shafts and perikarya. Some immunolabelled neurons resemble medium-sized, spiny projection neurons which suggests that the input from the hippocampal formation exerts a strong and direct influence on output pathways of nucleus accumbens.

The ventral striatopallidal complex: an immunocytochemical analysis of medium-sized striatal neurons and striatopallidal fibers in the basal forebrain of the rat

The borders of the ventral striatum and ventral pallidum of the rat brain have been studied with immunocytochemistry for two protein markers that are present in these regions. One of these, DARPP-32 (dopamine and cyclic AMP-regulated phosphoprotein, Mr 32,000), is specifically enriched in medium-sized spiny neurons of the neostriatum and in the projection of these neurons upon pallidal regions. The second protein, synaptophysin, a marker for nerve terminals, effectively labels pallidal synapses. In the ventral striatum, neurons strongly immunoreactive for DARPP-32 were densely packed throughout its three components, i.e., the fundus striati and the nucleus accumbens septi, the olfactory tubercle, and the cell bridges that connect the tubercle with the overlying caudatoputamen and the nucleus accumbens. In the ventral pallidum, axons and axon terminals immunoreactive for DARPP-32 and axon terminals immunoreactive for synaptophysin were clearly delineated. As defined by these markers, the ventral pallidum was traced rostroventrally from the globus pallidus to the superficial layers of the olfactory tubercle, medially to the insula Calleja magna and the lateral septum, laterally to the pyriform cortex, and caudally to the anterior amygdaloid area. The ventral striatum and pallidum were densely intermingled in parts of the olfactory tubercle and medial forebrain bundle regions, and clearly separated in more caudal regions. The insulae Callejae did not contain typical striatal or pallidal staining patterns. Our results indicate that the ventral striatopallidal complex in the rat extends both rostrocaudally and dorsoventrally, in a highly complex, intermingled fashion, throughout most of the basal forebrain.

New perspectives in basal forebrain organization of special relevance for neuropsychiatric disorders: the striatopallidal, amygdaloid, and corticopetal components of substantia innominata

The basal forebrain is critically involved in functions representing the highest levels of integration. Only recently has a relatively clear anatomical picture of this important area begun to emerge. The territory that has generally been referred to as the "substantia innominata" appears to be composed of portions of three recognizable forebrain structures: the ventral striatopallidal system, the extended amygdala and the magnocellular corticopetal system. (1) Rostrally, the striatopallidal system reaches ventrally to the base of the brain. (2) Caudal to the ventral extension of the striatopallidal system elements of the centromedial amygdala and bed nucleus of the stria terminalis are merged so that these two areas together with this subpallidal corridor form a large forebrain unit that might be described as an "extended amygdala". (3) Large cholinergic and non-cholinergic corticopetal neurons form a more or less continuous aggregate that is interwoven with the striatopallidal and extended amygdala systems in basal forebrain. Consideration of morphological and connectional characteristics of basal forebrain suggests that the corticopetal cell groups, together with magnocellular elements of the striatum, serve similar functional roles for the striatopallidal system, the extended amygdala, and the septal-diagonal band complex. Specifically, the output of medium spiny neurons in striatum, extended amygdala, and lateral septum are directed toward somewhat larger sparsely or moderately spiny neurons with radiating dendrites which in turn project to diencephalon and brainstem or provide either local feedback (e.g. in striatum) or distal feedback to cortex. The functional implications of this parallel processing of descending forebrain afferents are discussed.