Tolcapone enhances food-evoked dopamine efflux and executive memory processes mediated by the rat prefrontal cortex.

BACKGROUND AND RATIONALE: Genetic variations in catechol-O-methyl transferase (COMT) or administration of COMT inhibitors have a robust impact on cognition and executive function in humans. The COMT enzyme breaks down extracellular dopamine (DA) and has a particularly important role in the prefrontal cortex (PFC) where DA transporters are sparse. As such, the beneficial cognitive effects of the COMT inhibitor tolcapone are postulated to be the result of increased bioavailability of DA in the PFC. Furthermore, it has been shown previously that COMT inhibitors increase pharmacologically evoked DA but do not affect basal levels in the PFC. OBJECTIVES: The current study characterized the ability of tolcapone to increase DA release in response to behaviorally salient stimuli and improve performance of the delayed spatial win-shift (DSWSh) task. RESULTS AND CONCLUSIONS: Tolcapone enhanced PFC DA efflux associated with the anticipation and consumption of food when compared to saline controls. Chronic and acute treatment with tolcapone also reduced the number of errors committed during acquisition of the DSWSh. However, no dissociable effects were observed in experiments designed to selectively assay encoding or recall in well-trained animals, as both experiments showed improvement with tolcapone treatment. Taken together, these data suggest a generalized positive influence on cognition. Furthermore, these data support the conclusion of Apud and Weinberger (CNS Drugs 21:535-557, 2007) that agents which selectively potentiate PFC DA release may confer cognitive enhancement without the unwanted side effects produced by drugs that increase basal DA levels in cortical and subcortical brain regions.

Dopamine and serotonin interactions in the prefrontal cortex: insights on antipsychotic drugs and their mechanism of action.

Diminished activity within the prefrontal cortex (PFC) has been associated with many of the cognitive deficits that are observed in schizophrenia. It has been hypothesized that antipsychotic drugs (APDs) used to treat schizophrenia restore normal activity by antagonizing the dopamine (DA) D2 receptor, which is also known to modulate key ionic currents in the PFC. However, the hypothesis that an under-active cortical DA system is responsible for schizophrenic symptoms has been challenged by evidence that newer atypical APDs are weak antagonists at the D2 receptor but potent antagonists at the serotonin (5-HT) 2A receptor . This review examines how DA and 5-HT modulate cortical activity and how they may interact in ways that are relevant to schizophrenia. It is concluded that although D2 receptor antagonism remains a critical factor in restoring impaired cortical activity, effects on 5-HT receptors may act in a synergistic manner on NMDA and GABA currents to potentiate antipsychotic actions in the PFC.

Beyond bistability: biophysics and temporal dynamics of working memory.

Working memory has often been modeled and conceptualized as a kind of binary (bistable) memory switch, where stimuli turn on plateau-like persistent activity in subsets of cells, in line with many in vivo electrophysiological reports. A potentially related form of bistability, termed up- and down-states, has been studied with regard to its synaptic and ionic basis in vivo and in reduced cortical preparations. Also single cell mechanisms for producing bistability have been proposed and investigated in brain slices and computationally. Recently, however, it has been emphasized that clear plateau-like bistable activity is rather rare during working memory tasks, and that neurons exhibit a multitude of different temporally unfolding activity profiles and temporal structure within their spiking dynamics. Hence, working memory seems to be a highly dynamical neural process with yet unknown mappings from dynamical to computational properties. Empirical findings on ramping activity profiles and temporal structure will be reviewed, as well as neural models that attempt to account for it and its computational significance. Furthermore, recent in vivo, neural culture, and in vitro preparations will be discussed that offer new possibilities for studying the biophysical mechanisms underlying computational processes during working memory. These preparations have revealed additional evidence for temporal structure and spatio-temporally organized attractor states in cortical networks, as well as for specific computational properties that may characterize synaptic processing during high-activity states as during working memory. Together such findings may lay the foundations for highly dynamical theories of working memory based on biophysical principles.

Dopaminergic modulation of short-term synaptic plasticity in fast-spiking interneurons of primate dorsolateral prefrontal cortex.

Dopaminergic regulation of primate dorsolateral prefrontal cortex (PFC) activity is essential for cognitive functions such as working memory. However, the cellular mechanisms of dopamine neuromodulation in PFC are not well understood. We have studied the effects of dopamine receptor activation during persistent stimulation of excitatory inputs onto fast-spiking GABAergic interneurons in monkey PFC. Stimulation at 20 Hz induced short-term excitatory postsynaptic potential (EPSP) depression. The D1 receptor agonist SKF81297 (5 microM) significantly reduced the amplitude of the first EPSP but not of subsequent responses in EPSP trains, which still displayed significant depression. Dopamine (DA; 10 microM) effects were similar to those of SKF81297 and were abolished by the D1 antagonist SCH23390 (5 microM), indicating a D1 receptor-mediated effect. DA did not alter miniature excitatory postsynaptic currents, suggesting that its effects were activity dependent and presynaptic action potential dependent. In contrast to previous findings in pyramidal neurons, in fast-spiking cells, contribution of N-methyl-D-aspartate receptors to EPSPs at subthreshold potentials was not significant and fast-spiking cell depolarization decreased EPSP duration. In addition, DA had no significant effects on temporal summation. The selective decrease in the amplitude of the first EPSP in trains delivered every 10 s suggests that in fast-spiking neurons, DA reduces the amplitude of EPSPs evoked at low frequency but not of EPSPs evoked by repetitive stimulation. DA may therefore improve detection of EPSP bursts above background synaptic activity. EPSP bursts displaying short-term depression may transmit spike-timing-dependent temporal codes contained in presynaptic spike trains. Thus DA neuromodulation may increase the signal-to-noise ratio at fast-spiking cell inputs.

Unmanageable motivation in addiction: a pathology in prefrontal-accumbens glutamate transmission.

Prime diagnostic criteria for drug addiction include uncontrollable urges to obtain drugs and reduced behavioral responding for natural rewards. Cellular adaptations in the glutamate projection from the prefrontal cortex (PFC) to the nucleus accumbens have been discovered in rats withdrawn from cocaine that may underlie these cardinal features of addiction. A hypothesis is articulated that altered G protein signaling in the PFC focuses behavior on drug-associated stimuli, while dysregulated PFC-accumbens synaptic glutamate transmission underlies the unmanageable motivation to seek drugs.

Dopamine modulation of neuronal function in the monkey prefrontal cortex.

We developed a brain slice preparation that allowed us to apply whole-cell recordings to examine the electrophysiological properties of identified synapses, neurons, and local circuits in the dorsolateral prefrontal cortex (DLPFC) of macaque monkeys. In this article, we summarize the results from some of our recent and current in vitro studies in the DLPFC with special emphasis on the modulatory effects of dopamine (DA) receptor activation on pyramidal and nonpyramidal cell function in superficial layers in DLPFC areas 46 and 9.

Bidirectional dopamine modulation of GABAergic inhibition in prefrontal cortical pyramidal neurons.

Dopamine regulates the activity of neural networks in the prefrontal cortex that process working memory information, but its precise biophysical actions are poorly understood. The present study characterized the effects of dopamine on GABAergic inputs to prefrontal pyramidal neurons using whole-cell patch-clamp recordings in vitro. In most pyramidal cells, dopamine had a temporally biphasic effect on evoked IPSCs, producing an initial abrupt decrease in amplitude followed by a delayed increase in IPSC amplitude. Using receptor subtype-specific agonists and antagonists, we found that the initial abrupt reduction was D2 receptor-mediated, whereas the late, slower developing enhancement was D1 receptor-mediated. Linearly combining the effects of the two agonists could reproduce the biphasic dopamine effect. Because D1 agonists enhanced spontaneous (sIPSCs) but did not affect miniature (mIPSCs) IPSCs, it appears that D1 agonists caused larger evoked IPSCs by increasing the intrinsic excitability of interneurons and their axons. In contrast, D2 agonists had no effects on sIPSCs but did produce a significant reduction in mIPSCs, suggestive of a decrease in GABA release probability. In addition, D2 agonists reduced the postsynaptic response to a GABA(A) agonist. D1 and D2 receptors therefore regulated GABAergic activity in opposite manners and through different mechanisms in prefrontal cortex (PFC) pyramidal cells. This bidirectional modulation could have important implications for the computational properties of active PFC networks.

The role of RNA editing of kainate receptors in synaptic plasticity and seizures.

The ionotropic glutamate receptor subunit GluR6 undergoes developmentally and regionally regulated Q/R site RNA editing that reduces the calcium permeability of GluR6-containing kainate receptors. To investigate the functional significance of this editing in vivo, we engineered mice deficient in GluR6 Q/R site editing. In these mutant mice but not in wild types, NMDA receptor-independent long-term potentiation (LTP) could be induced at the medial perforant path-dentate gyrus synapse. This indicates that kainate receptors with unedited GluR6 subunits can mediate LTP. Behavioral analyses revealed no differences from wild types, but mutant mice were more vulnerable to kainate-induced seizures. Together, these results suggest that GluR6 Q/R site RNA editing may modulate synaptic plasticity and seizure vulnerability.

Dopamine D1/D5 receptor modulation of excitatory synaptic inputs to layer V prefrontal cortex neurons.

Dopamine acts mainly through the D1/D5 receptor in the prefrontal cortex (PFC) to modulate neural activity and behaviors associated with working memory. To understand the mechanism of this effect, we examined the modulation of excitatory synaptic inputs onto layer V PFC pyramidal neurons by D1/D5 receptor stimulation. D1/D5 agonists increased the size of N-methyl-d-aspartate (NMDA) component of excitatory postsynaptic currents (EPSCs) through a postsynaptic mechanism. In contrast, D1/D5 agonists caused a slight reduction in the size of the non-NMDA component of EPSCs through a small decrease in release probability. With 20 Hz synaptic trains, we found that the D1/D5 agonists increased depolarization of summating the NMDA component of excitatory postsynaptic potential (EPSP). By increasing the NMDA component of EPSCs, yet slightly reducing release, D1/D5 receptor activation selectively enhanced sustained synaptic inputs and equalized the sizes of EPSPs in a 20-Hz train.

Neurocomputational models of working memory.

During working memory tasks, the firing rates of single neurons recorded in behaving monkeys remain elevated without external cues. Modeling studies have explored different mechanisms that could underlie this selective persistent activity, including recurrent excitation within cell assemblies, synfire chains and single-cell bistability. The models show how sustained activity can be stable in the presence of noise and distractors, how different synaptic and voltage-gated conductances contribute to persistent activity, how neuromodulation could influence its robustness, how completely novel items could be maintained, and how continuous attractor states might be achieved. More work is needed to address the full repertoire of neural dynamics observed during working memory tasks.

Dopamine-mediated stabilization of delay-period activity in a network model of prefrontal cortex.

The prefrontal cortex (PFC) is critically involved in working memory, which underlies memory-guided, goal-directed behavior. During working-memory tasks, PFC neurons exhibit sustained elevated activity, which may reflect the active holding of goal-related information or the preparation of forthcoming actions. Dopamine via the D1 receptor strongly modulates both this sustained (delay-period) activity and behavioral performance in working-memory tasks. However, the function of dopamine during delay-period activity and the underlying neural mechanisms are only poorly understood. Recently we proposed that dopamine might stabilize active neural representations in PFC circuits during tasks involving working memory and render them robust against interfering stimuli and noise. To further test this idea and to examine the dopamine-modulated ionic currents that could give rise to increased stability of neural representations, we developed a network model of the PFC consisting of multicompartment neurons equipped with Hodgkin-Huxley-like channel kinetics that could reproduce in vitro whole cell and in vivo recordings from PFC neurons. Dopaminergic effects on intrinsic ionic and synaptic conductances were implemented in the model based on in vitro data. Simulated dopamine strongly enhanced high, delay-type activity but not low, spontaneous activity in the model network. Furthermore the strength of an afferent stimulation needed to disrupt delay-type activity increased with the magnitude of the dopamine-induced shifts in network parameters, making the currently active representation much more stable. Stability could be increased by dopamine-induced enhancements of the persistent Na(+) and N-methyl-D-aspartate (NMDA) conductances. Stability also was enhanced by a reduction in AMPA conductances. The increase in GABA(A) conductances that occurs after stimulation of dopaminergic D1 receptors was necessary in this context to prevent uncontrolled, spontaneous switches into high-activity states (i.e., spontaneous activation of task-irrelevant representations). In conclusion, the dopamine-induced changes in the biophysical properties of intrinsic ionic and synaptic conductances conjointly acted to highly increase stability of activated representations in PFC networks and at the same time retain control over network behavior and thus preserve its ability to adequately respond to task-related stimuli. Predictions of the model can be tested in vivo by locally applying specific D1 receptor, NMDA, or GABA(A) antagonists while recording from PFC neurons in delayed reaction-type tasks with interfering stimuli.

Synaptic plasticity in morphologically identified CA1 stratum radiatum interneurons and giant projection cells.

Long-term potentiation (LTP) of synaptic efficacy was examined in interneurons and giant cells in the stratum radiatum region of the hippocampal CA1 subfield. Cells were visually selected using differential interference contrast (DIC) optics and filled with biocytin while being recorded using whole-cell patch-clamp techniques. Electrophysiological criteria, including spike height, width, and degree of spike adaptation shown to sustained depolarization, proved inadequate for differentiating interneurons from giant cells. We found that cells in the stratum radiatum, however, could be reliably differentiated using DIC optics or following intracellular staining. The response of the two cell types to tetanic stimulation further dissociated them. Long-term potentiation, dependent on the activation of NMDAr (N-methyl-D-aspartate receptors), could reliably be induced in interneurons with stimuli administered at 200 Hz, but not 100 Hz. Giant cells, in contrast, exhibited NMDA receptor-dependent LTP in response to 100-Hz stimuli, but not the 200-Hz stimuli. LTP induction in interneurons also appeared temperature-dependent, being much more robust at 34 degrees C than at room temperature. The LTP in both cell types required postsynaptic calcium influx, and was not due to the passive propagation of LTP induction in neighboring pyramidal cells. These results suggest that different cell types within the hippocampal formation may preferentially alter synaptic connectivity in a frequency-specific manner.

Developing a neuronal model for the pathophysiology of schizophrenia based on the nature of electrophysiological actions of dopamine in the prefrontal cortex.

This review covers some recent findings of the electrophysiological mechanisms through which mesocortical dopamine modulates prefrontal cortical neurons. Dopamine has been shown to modulate several ionic conductances located along the soma-dendritic axis of prefrontal cortical pyramidal neurons. These ionic currents include high-voltage-activated calcium currents and slowly inactivating Na+ and K+ currents. They contribute actively in processing functionally segregated inputs during synaptic integration. In addition, dopamine mainly depolarizes the fast-spiking subtype of local GABAergic interneurons that connect the pyramidal neurons. This latter action can indirectly control pyramidal cell excitability. These electrophysiological data indicate that the actions of dopamine are neither "excitatory" nor "inhibitory" in pyramidal prefrontal cortex neurons. Rather, the actions of dopamine are dependent on somadendritic loci, timing of the arrival of synaptic inputs, strength of synaptic inputs, as well as the membrane potential range at which the PFC neuron is operating at a given moment. Based on available electrophysiological findings, a neuronal model of the pathophysiology of schizophrenia is presented. This model proposes that episodic hypo- and hyperactivity of the PFC and the associated dysfunctional mesocortical dopamine system (and their interconnected brain regions) may coexist in the same schizophrenic patient in the course of the illness. We hypothesize that the dysfunctional mesocortical dopamine input to the PFC may lead to abnormal modulation of ionic channels distributed in the dendritic-somatic compartments of PFC pyramidal neurons that project to the ventral tegmental area and/or nucleus accumbens. In some schizophrenics, a reduction of mesocortical dopamine to below optimal levels and/or a loss of local GABAergic inputs may result in a dysfunctional integration of extrinsic associative inputs by Ca2+ channel activity in the distal dendrites of PFC pyramidal neurons. This may account for the patients' distractibility caused by their inability to focus only on relevant external inputs. In contrast, in acute stress or psychotic episodes, an associated abnormal elevation of mesocortical dopamine transmission may greatly influence distal dendritic Ca2+ channel-mediated signal-processing mechanisms. This can enhance possible reverberative activity between adjacent interconnected pyramidal neurons via the effects of dopamine on the slowly inactivating Na+, K+, and soma-dendritic Ca2+ currents. The effects of high levels of PFC dopamine in this case may contribute to behavioral perseveration and stereotypy so that the patients are unable to use new external cues to modify ongoing behaviors.

D1 receptor modulation of hippocampal-prefrontal cortical circuits integrating spatial memory with executive functions in the rat.

Dopamine (DA) within the prefrontal cortex (PFC) plays an important role in modulating the short-term retention of information during working memory tasks. In contrast, little is known about the role of DA in modulating other executive aspects of working memory such as the use of short-term memory to guide action. The present study examined the effects of D1 and D2 receptor blockade in the PFC on foraging by rats on a radial arm maze under two task conditions: (1) a delayed task in which spatial information acquired during a training phase was used 30 min later to guide prospective responses, and (2) a nondelayed task that was identical to the test phase of the delayed task but lacked a training phase, thereby depriving rats of previous information about the location of food on the maze. In experiment 1, microinjections of the D1 antagonist SCH-23390 (0.05, 0.5, or 5 microg/µl), but not the D2 antagonist sulpiride (0.05, 0.5, or 5 microg/microl), into the prelimbic region of the PFC before the test phase disrupted performance of the delayed task without affecting response latencies. In contrast, neither drug affected performance of the nondelayed task. In the present study, we also investigated the role of D1 receptors in modulating activity in hippocampal-PFC circuits during delayed responding. Unilateral injections of SCH-23390 into the PFC in the hemisphere contralateral to a microinjection of lidocaine into the hippocampus severely disrupted performance of the delayed task. Thus, the ability to use previously acquired spatial information to guide responding 30 min later on a radial arm maze requires D1 receptor activation in the PFC and D1 receptor modulation of hippocampal inputs to the PFC. These data suggest that D1 receptors in the PFC are involved in working memory processes other than just the short-term active retention of information and also provide direct evidence for DA modulation of limbic-PFC circuits during behavior.

Contributions of voltage-gated Ca2+ channels in the proximal versus distal dendrites to synaptic integration in prefrontal cortical neurons.

The electrogenesis of synaptically activated dendritic Ca2+-mediated potentials, which may contribute to synaptic signal integration in pyramidal cells, was examined in rat layers V-VI prefrontal cortical (PFC) neurons in vitro. Intrasomatically recorded suprathreshold synaptic responses evoked by stimulation of the distal dendrites were attenuated by focal Cd2+ application to the proximal apical dendritic stem (100-200 micron from soma), but not to the apical dendritic tuft (>500 micron from soma). With use of intracellular QX-314 and Cs+ to block Na+ and K+ currents, intrasomatic recordings revealed that the Cd2+-induced attenuation of synaptic responses was attributable to the blockade of a dendritic Ca2+-mediated "hump" potential and high-threshold Ca2+ spike activated by NMDA EPSPs. The hump potential was not blocked by bath application of Ni2+ (100 microM) but was blocked by focal application of Cd2+ to the proximal but not distal apical dendrites, suggesting that it was generated by Ca2+ channels located in the proximal dendrites. Direct patch-clamp recordings made from the distal apical tuft of layers V-VI PFC neurons revealed that layers I-II synaptic stimulation or intradendritic depolarizing current pulses evoked tetrodotoxin- and QX-314-sensitive Na+ spikes. Unlike in the stem of the apical dendrite, Ca2+ spikes were not easily evoked in the distal apical tuft when Na+ channels were blocked. When triggered, the Cd2+-sensitive Ca2+ spikes in the dendritic tuft were nonregenerative and had very high activation thresholds (approximately +10 mV). These results suggested that the high voltage-activated Ca2+ potentials that amplify distal EPSPs are primarily generated in the proximal stem of the apical dendrite and not within the fine dendritic branches of the apical tuft of layers V-VI PFC neurons.

Selective roles for hippocampal, prefrontal cortical, and ventral striatal circuits in radial-arm maze tasks with or without a delay.

The hippocampus, the prefrontal cortex, and the ventral striatum form interconnected neural circuits that may underlie aspects of spatial cognition and memory. In the present series of experiments, we investigated functional interactions between these areas in rats during the performance of delayed and nondelayed spatially cued radial-arm maze tasks. The two-phase delayed task consisted of a training phase that provided rats with information about where food would be located on the maze 30 min later during a test phase. The single-phase nondelayed task was identical to the test phase of the delayed task, but in the absence of a training phase rats lacked previous knowledge of the location of food on the maze. Transient inactivation of the ventral CA1/subiculum (vSub) by a bilateral injection of lidocaine disrupted performance on both tasks. Lidocaine injections into the vSub on one side of the brain and the prefrontal cortex on the other transiently disconnected these two brain regions and significantly impaired foraging during the delayed task but not the nondelayed task. Transient disconnections between the vSub and the nucleus accumbens produced the opposite effect, disrupting foraging during the nondelayed task but not during the delayed task. These data suggest that serial transmission of information between the vSub and the prefrontal cortex is required when trial-unique, short-term memory is used to guide prospective search behavior. In contrast, exploratory goal-directed locomotion in a novel situation not requiring previously acquired information about the location of food is dependent on serial transmission between the hippocampus and the nucleus accumbens. These results indicate that different aspects of spatially mediated behavior are subserved by separate, distributed limbic-cortical-striatal networks.

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.

A selective role for dopamine in the nucleus accumbens of the rat in random foraging but not delayed spatial win-shift-based foraging.

The role of mesoaccumbens dopamine (DA) in radial-arm maze foraging is assessed by infusing low doses of the DA antagonist haloperidol into the nucleus accumbens (N.Acc.). Infusions of haloperidol (0, 125, 250 or 500 ng/0.5 microliter) into the N.Acc. of well-trained rats dose-dependently increase the number of re-entries to arms (errors) during the random foraging task, in which 4 arms on an 8-arm maze are baited randomly. However, in a separate group of animals, similar infusions produce no impairment when delivered prior to the test phase of the delayed spatial win-shift task, which require the animal to acquire information during a training phase, and to use that information 30 min later, during a test phase. These results suggest that DA neurotransmission in the N.Acc. is crucial for foraging behavior when there is ambiguity about the location of reward in a spatial environment, but is not needed for efficient foraging behavior when an animal has previous information as to the location of rewarding stimuli. The results are discussed with respect to of the underlying physiological interactions between limbic glutamate and mesoaccumbens DA transmission in the N.Acc.

Electrophysiological and morphological properties of layers V-VI principal pyramidal cells in rat prefrontal cortex in vitro.

This study examined the electrophysiological and morphological characteristics of layers V-VI pyramidal prefrontal cortex (PFC) neurons. In vitro intracellular recordings coupled with biocytin injections that preserved some of the PFC efferents to the nucleus accumbens (NAc) were made in brain slices. Four principal pyramidal cell types were identified and classified as regular spiking (RS) (19%), intrinsic bursting (IB) (64%), repetitive oscillatory bursting (ROB) (13%), and intermediate (IM) (4%) types. All PFC cells exhibited either subthreshold oscillation in membrane voltage or pacemaker-like rhythmic firing. IB neurons were demonstrated electrophysiologically and cytochemically to be PFC-->NAc neurons. In all IB and some RS neurons, a tetrodotoxin-sensitive, slowly inactivating Na+ current and a transient Ni(2+)-sensitive, low-threshold Ca2+ current mediated subthreshold inward rectification. During sustained membrane depolarization, the Na+ current was opposed by a 4-aminopyridine-sensitive, outwardly rectifying, slowly inactivating K+ current. Together, these three currents controlled the firing threshold of the PFC neurons. All IB and ROB cells also had postspike Ca(2+)-mediated depolarizing afterpotentials, postburst Ca(2+)-dependent after hyperpolarizations, and low- and high-threshold Ca2+ spikes. In addition, ROB cells had a hyperpolarizing "sag" mediated by the cationic conductance, Ih. IB and ROB neurons had extensive dendritic trees and radially ascending or tangentially projecting axon collaterals. RS and IM cells had comparatively simpler morphological profiles. These electrophysiological and morphological properties of the four principal pyramidal PFC cell types have provided valuable details for understanding further how PFC processes input and transmit outputs to regions such as the NAc.

Dopamine D1 receptor actions in layers V-VI rat prefrontal cortex neurons in vitro: modulation of dendritic-somatic signal integration.

The ionic mechanisms by which dopamine (DA) regulates the excitability of layers V-VI prefrontal cortex (PFC) output neurons (including those that project to the nucleus accumbens) were investigated in rat brain slices using in vitro intracellular recording techniques. DA or the D1 receptor agonist SKF38393, but not the D2 agonist quinpirole, reduced the first spike latency and lowered the firing threshold of the PFC neurons in response to depolarizing current pulses. This was accomplished by enhancing the duration of a tetradotoxinsensitive, slowly inactivating Na+ current and attenuating a slowly inactivating, outwardly rectifying, dendrotoxin-sensitive K+ current. Furthermore, D1 receptor stimulation attenuated high-threshold Ca2+ spike(s) (HTS) evoked primarily from the apical dendrites of these PFC neurons. Taken together, these data suggest that D1 receptor stimulation on layers V-VI pyramidal PFC neurons: (1) restricts the effects of inputs to the apical dendrites of these neurons by attenuating the dendritic HTS-mediated amplification of such inputs; and (2) potentiates the influence of local inputs from neighboring deep layers V-VI neurons by enhancing the slowly inactivating Na+ current and attenuating the slowly inactivating K+ current. By influencing the input/output characteristics of PFC-->NAc neurons, DA may play an important role in the processes through which PFC signals are translated into action.