The NMDA receptor antagonist CPP suppresses long-term potentiation in the rat hippocampal-accumbens pathway in vivo

Formation of a morphine-conditioned place preference does not change the size of evoked potentials in the ventral hippocampus-nucleus accumbens projection

In opioid addiction, cues and contexts associated with drug reward can be powerful triggers for drug craving and relapse. The synapses linking ventral hippocampal outputs to medium spiny neurons of the accumbens may be key sites for the formation and storage of associations between place or context and reward, both drug-related and natural. To assess this, we implanted rats with electrodes in the accumbens shell to record synaptic potentials evoked by electrical stimulation of the ventral hippocampus, as well as continuous local-field-potential activity. Rats then underwent morphine-induced (10 mg/kg) conditioned-place-preference training, followed by extinction. Morphine caused an acute increase in the slope and amplitude of accumbens evoked responses, but no long-term changes were evident after conditioning or extinction of the place preference, suggesting that the formation of this type of memory does not lead to a net change in synaptic strength in the ventral hippocampal output to the accumbens. However, analysis of the local field potential revealed a marked sensitization of theta- and high-gamma-frequency activity with repeated morphine administration. This phenomenon may be linked to the behavioral changes—such as psychomotor sensitization and the development of drug craving—that are associated with chronic use of addictive drugs.

The role of dopamine-dependent negative feedback in the hippocampus-basal ganglia-thalamus-hippocampus loop in the extinction of responses

A mechanism for the extinction of the responses of hippocampal and dopaminergic neurons to repeated sensory stimuli is proposed, based on dopamine-dependent negative feedback in the hippocampus-basal ganglia-thalamus-hippocampus loop. Activation of hippocampal neurons evoked by a new stimulus facilitates the appearance of responses in dopaminergic neurons as a result of disinhibition via striopallidal cells of the nucleus accumbens and ventral pallidum. However, increases in dopamine levels and activation of D2 receptors on striopallidal cells, facilitating depression of hippocampal inputs, prevent disinhibition of dopaminergic neurons, such that their responses start to decline. Subsequent reductions in actions on D1 receptors lead to decreases in the efficiency of excitation both of neurons in hippocampal field CA1 and strionigral cells in the nucleus accumbens. The direct pathway via the basal ganglia mediates disinhibition of the thalamic nucleus reuniens, exciting neurons in field CA1, which leads to extinction of the responses of hippocampal neurons, decreases in disinhibition of dopaminergic cells, and further extinction of their responses.

Baroreflexes of the rat. V. Tetanus-induced potentiation of ADN A-fiber responses at the NTS

In a long-term neuromuscular blocked (NMB) rat preparation, tetanic stimulation of the aortic depressor nerve (ADN) enhanced the A-fiber evoked responses (ERs) in the cardiovascular region, the nucleus of the solitary tract (dmNTS). The potentiation persisted for at least several hours and may be a mechanism for adaptive adjustment of the gain of the baroreflex, with functional implications for blood pressure regulation. Using a capacitance electrode, we selectively stimulated A-fibers and acquired a stable 10-h "A-fiber only" ER baseline at the dmNTS. Following baseline, an A+C-fiber activating tetanus was applied to the ADN. The tetanus consisted of 1,000 "high current" pulses (10 trains; 300 mus, 100 Hz, 1 s), with intertrain interval of 9 s. A 10-h A-fiber only posttetanic test phase repeated the stimulus pattern of the baseline. Fourteen tetanus experiments were done in 12 rats. Compared with the baseline before tetanus, the A-fiber ER magnitudes of posttetanus hours were larger [F(13, 247) = 3.407, P < .001]; additionally, the 10-h posttetanus magnitude slopes were more positive than during 10 h before tetanus (df = 13; t = -3.47; P < 0.005); thus, an ADN A+C fiber-activating tetanus produced increases in the magnitude of the A-fiber ERs in the dmNTS that persisted for several hours. In an additional rat, application of an NMDA receptor antagonist, prior to the tetanus, blocked the potentiation effect. The stimulus protocols, magnitude and duration of the effect, and pharmacology resemble associative long-term potentiation (LTP).

Opiate withdrawal modifies synaptic plasticity in subicular-nucleus accumbens pathway in vivo

Subiculum receives output of hippocampal CA1 neurons and projects glutamatergic synapses onto nucleus accumbens (NAc), the subicular-NAc pathway linking memory and reward system. It is unknown whether morphine withdrawal influences synaptic plasticity in the subicular-NAc pathway. Here, we recorded the field excitatory postsynaptic potential (EPSP) within the shell of NAc by stimulating ventral subiculum in anesthetized adult rats. We found that high frequency stimulation (HFS, 200 Hz) induced long-term potentiation (LTP) but low frequency stimulation (LFS, 1 Hz) failed to induce long-term depression (LTD) in control animals. However, behavioral stress enabled LFS to induce a reliable LTD (sLTD) that was dependent on the glucocorticoid receptors. Both LTP and sLTD were prevented by the N-methyl-d-aspartate receptor antagonist AP-5. After repeated morphine treatment for 12 days, acute withdrawal (12 h) impaired LTP but had no effect on sLTD; prolonged withdrawal (4 days) restored the LTP but impaired the sLTD. Remarkably, basal synaptic efficacy reflected by baseline EPSP amplitude was potentiated in acute withdrawal but was depressed in prolonged withdrawal. Thus, acute and prolonged opiate withdrawal may cause endogenous LTP and LTD in the subicular-NAc pathway that occludes the subsequent induction of synaptic plasticity, demonstrating adaptive changes of the NAc functions during opiate withdrawal.

Ketamine induces dopamine-dependent depression of evoked hippocampal activity in the nucleus accumbens in freely moving rats

Noncompetitive NMDA receptor antagonists, such as ketamine, induce a transient schizophrenia-like state in healthy individuals and exacerbate psychosis in schizophrenic patients. In rodents, noncompetitive NMDA receptor antagonists induce a behavioral syndrome that represents an experimentally valid model of schizophrenia. Current experimental evidence has implicated the nucleus accumbens in the pathophysiology of schizophrenia and the psychomimetic actions of ketamine. In this study, we have demonstrated that acute systemic administration of ketamine, at a dose known to produce hyperlocomotion and stereotypy, depressed the amplitude of the monosynaptic component of fimbria-evoked field potentials recorded in the nucleus accumbens. A similar effect was observed using the more selective antagonist dizocilpine maleate, indicating the depression was NMDA receptor dependent. Paired-pulse facilitation was enhanced concomitantly with, and in proportion to, ketamine-induced depressed synaptic efficacy, indicative of a presynaptic mechanism of action. Notably, the depression of field potentials recorded in the nucleus accumbens was markedly reduced after a focal 6-hydroxydopamine lesioning procedure in the nucleus accumbens. More specifically, pretreatment with the D2/D4 antagonist haloperidol, but not the D1 antagonist SCH23390 blocked ketamine-induced depression of nucleus accumbens responses. Our findings provide supporting evidence for the contemporary theory of schizophrenia as aberrant excitatory neurotransmission at the level of the nucleus accumbens.

Modulation of hippocampal and amygdalar-evoked activity of nucleus accumbens neurons by dopamine: cellular mechanisms of input selection

Inputs from multiple sites in the telencephalon, including the hippocampus and basolateral amygdala (BLA), converge on neurons in the nucleus accumbens (NAc), and dopamine (DA) is believed to play an essential role in the amplification and gating of these different limbic inputs. The present study used extracellular single-unit recordings of NAc neurons in combination with chronoamperometric sampling of mesoaccumbens DA efflux to assess the importance of DA in the integration of different limbic inputs to the NAc. Tetanic stimulation of the fimbria potentiated hippocampal-evoked firing activity of NAc neurons and increased DA extracellular levels. Systemic administration of the D(1) receptor antagonist SCH23390 or the NMDA receptor antagonist CPP abolished the potentiation of hippocampal-evoked activity and produced a D(2) receptor-mediated suppression of evoked firing. In neurons that received converging input from the hippocampus and BLA, fimbria tetanus potentiated hippocampal-evoked firing activity and suppressed BLA-evoked activity in the same neurons. Both D(1) and NMDA receptors participated in the potentiation of fimbria-evoked activity, whereas the suppression of BLA-evoked activity was blocked by either D(1) receptor antagonism with SCH23390 or the adenosine A(1) antagonist 8-cyclopentyl-1,2-dimethylxanthine. Coincidental tetanus of both the fimbria and BLA resulted in potentiation of both inputs, indicating that DA and adenosine-mediated suppression of BLA-evoked firing was activity-dependent. These data suggest that increases in mesoaccumbens DA efflux by hippocampal afferents to the NAc play a critical role in an input selection mechanism, which can ensure preferential responding to the information conveyed from the hippocampus to the ventral striatum.

Short- and long-term plasticity of the hippocampus to nucleus accumbens and prefrontal cortex pathways in the rat, in vivo

The pathways from the hippocampal formation to the nucleus accumbens and the prefrontal cortex are likely to play a role in several aspects of learning and memory. In the present study we addressed the question of how plastic changes in these structures may occur simultaneously. This question can be studied in an appropriate way in the hippocampal/fornix-fimbria to prefrontal cortex/nucleus accumbens system, since electrical stimulation of the fornix-fimbria fibre bundle evokes characteristic field potentials in the two target areas simultaneously. First, we examined the termination field in the nucleus accumbens (medial shell and core region with an extension into the ventro-medial caudate-putamen) and the prefrontal cortex (deeper layers of the ventral prelimbic and ventral infralimbic areas) by recording single unit activity evoked by stimulation of fornix-fimbria fibres in halothane anaesthetized rats. Second, we studied short-term plasticity, namely paired pulse facilitation, in these two areas upon stimulation of the fornix-fimbria fibres. In the nucleus accumbens, paired pulse facilitation was encountered for double pulse intervals between 25 and 500 ms, peaking around 100 ms. In the medial prefrontal cortex it was confined to intervals between 25 and 200 ms, with a peak around 75 ms. Third, we investigated whether LTP could be elicited simultaneously in the two target structures by a single tetanic stimulation (50 Hz, 2 s) of the fornix-fimbria fibres. LTP that was sustained for more than 90 min in the medial prefrontal cortex, reached levels of 130% of control values. In the nucleus accumbens, however, only a transient form of potentiation was found which lasted no more than 60 min. These data show that synaptic weights can be changed in several target structures of the hippocampal formation, simultaneously, in a distributed way.

Nucleus accumbens lesions impair context, but not cue, conditioning in rats

Previous work has provided evidence of a role for the hippocampal formation in contextual as opposed to cue conditioning. Similar deficits have been observed after transection of the fimbria/fornix, part of which consists of the hippocampal-nucleus accumbens (N.Acc) connection arising from both the dorsal and ventral subiculum. By means of electrolytic lesions of the N.Acc, we showed that the subiculo-accumbens projection appears to participate in aversive conditioning to context, but not to a cue (tone). Freezing, measured as an index of learning, in the experimental context was greatly reduced in animals with lesions of the N.Acc, as compared with sham-operated controls. No difference was found in freezing to a distinct tone. These data lend further support to the notion that the N.Acc is an important interface between limbic structures and motor output.

Differential effects of lidocaine infusions into the ventral CA1/subiculum or the nucleus accumbens on the acquisition and retention of spatial information

Reversible, lidocaine-induced lesions of the CA1/subicular subfield of the ventral hippocampus or the shell region of the nucleus accumbens (N.Acc.) were used to assess the roles of these structure during the acquisition and retention of a spatial response as measured by the Morris water-maze task. Acquisition and retention tests were administered over 2 phases of 6 trials, respectively. Rats receiving reversible lesions of the ventral CA1/subiculum prior to the acquisition phase of this task required significantly longer path lengths to find a hidden platform than animals which received control infusions of artificial cerebrospinal fluid. Rats with similar lesions to the N.Acc. were unimpaired. During the retention phase, 30 min after the acquisition phase, rats with prior ventral CA1/subiculum or N.Acc. lesions had similar path lengths to control animals. Lidocaine infusions into either the ventral CA1/subiculum or N.Acc. prior to the retention phase did not impair performance relative to control animals. These results suggest that the N.Acc. is not involved in either the acquisition or retention of spatial information. In contrast, the ventral CA1/subiculum does appear to be involved in the initial use of novel spatial information necessary for the performance of a spatially mediated escape response, but is not involved in the retention or retrieval of previously acquired spatial information.

NMDA receptors and plasticity in adult primate somatosensory cortex

Topographic maps in adult primate somatosensory cortex are capable of dramatic reorganizations after peripheral nerve injuries. In the present experiments, we have deprived a circumscribed portion of the hand map in somatosensory cortex of our adult squirrel monkeys by transecting the median nerve to one hand, and evaluated the hypothesis that N-methyl-d-aspartate (NMDA) glutamatergic receptors are necessary for the reorganization that follows within four weeks. In one monkey, we confirm previous results demonstrating that the deprived cortex has regained responsiveness in its expanse four weeks after median nerve transection. However, in three monkeys in which NMDA receptors were concurrently blocked, most of the deprived cortex remained unresponsive. Thus, much of the cortical "recovery" that typically follows peripheral nerve injury in adult monkeys is apparently dependent on NMDA receptors and may well be due to Hebbian-like changes in synaptic strength. Perhaps the elimination of the normally dominant inputs to "median nerve cortex" permits the gradual strengthening of correlations between the activity of the formally impotent presynaptic and deprived postsynaptic elements. These enhanced correlations may also have been made possible by reductions in intracortical inhibition as a necessary but not sufficient condition.

Dopamine autoreceptor sensitivity is unchanged in rat nucleus accumbens after chronic haloperidol treatment: an in vivo and in vitro voltammetric study

Fast cyclic voltammetry was used to assess the effects of chronic oral haloperidol treatment (0.7 mg/kg/day for 21 days) on the sensitivity of dopamine autoreceptors in the rat nucleus accumbens both in vivo and in vitro. Evoked dopamine overflow was significantly reduced after chronic haloperidol treatment, but the sensitivity of dopamine overflow to sulpiride, an antagonist at release-inhibiting dopamine autoreceptors, and quinpirole, an agonist at these receptors, was unchanged. The estimated EC50 values for quinpirole and sulpiride (52 and 60 nM respectively) obtained in vitro and the receptor distribution profiles published in the literature suggest that the autoreceptors involved in this modulation are mainly of the D3 subtype. The finding that the reduced dopamine overflow in the nucleus accumbens observed after chronic treatment with a classical neuroleptic is not due to dopamine autoreceptor supersensitivity may therefore be the first functional evidence for unchanged autoreceptor activity in the nucleus accumbens, supporting biochemical findings of a lack of D3 autoreceptor up-regulation after chronic haloperidol treatment. It lends further support to the assumption that the long-term changes occurring during chronic neuroleptic treatment may not lie at the level of presynaptic dopamine receptor regulation.