Altered frontal cortical dopaminergic transmission in monkeys after subchronic phencyclidine exposure: involvement in frontostriatal cognitive deficits

Long-term exposure to the psychotomimetic drug phencyclidine produces prefrontal cortical cognitive and dopaminergic dysfunction in rats and monkeys, effects possibly relevant to the frontal cortical impairments of schizophrenia. In the present study, the effects of subchronic phencyclidine administration (0.3 mg/kg twice-daily for 14 days) on monoamine systems in the monkey brain were examined and related to cognitive performance on an object retrieval/detour task, which has been linked with frontostriatal function. Long-term (14 days) administration of phencyclidine resulted in a marked and persistent reduction in dopamine utilization in the frontal cortex. Moreover, the degree of cognitive impairment in phencyclidine-treated monkeys correlated significantly with the magnitude of dopaminergic inhibition within the dorsolateral prefrontal cortex and prelimbic cortex. No specific correlation was measured for dopamine utilization in other cortical regions or for indices of serotonin transmission in any brain region. These data show that repeated exposure to phencyclidine reduces prefrontal cortical dopamine transmission, and this inhibition of dopaminergic function is associated with performance impairments on a task sensitive to frontostriatal cognitive dysfunction. Thus, the cognitive deficits of phencyclidine-treated monkeys, as in schizophrenia, appear to be mediated, in part, by reduced dopaminergic function in specific subregions of the frontal cortex.     

A functional magnetic resonance imaging study of the effects of pergolide, a dopamine receptor agonist, on component processes of working memory

Working memory is an important cognitive process dependent on a network of prefrontal and posterior cortical regions. In this study we tested the effects of the mixed D1-D2 dopamine receptor agonist pergolide on component processes of human working memory using functional magnetic resonance imaging (fMRI). An event-related trial design allowed separation of the effects on encoding, maintenance, and retrieval processes. Subjects were tested with spatial and object memoranda to investigate modality-specific effects of dopaminergic stimulation. We also measured baseline working memory capacity as previous studies have shown that effects of dopamine agonists vary with working memory span. Pergolide improved reaction time for high-span subjects and impaired reaction time for low-span subjects. This span-dependent change in behavior was accompanied by span-dependent changes in delay-related activity in the premotor cortex. We also found evidence for modality-specific effects of pergolide only during the response period. Pergolide increased activity for spatial memoranda and decreased activity for object memoranda in task-related regions including the prefrontal and parietal cortices.     

Under the curve: critical issues for elucidating D1 receptor function in working memory

It has been postulated that spatial working memory operates optimally within a limited range of dopamine transmission and D1 dopamine receptor signaling in prefrontal cortex. Insufficiency in prefrontal dopamine, as in aging, and excessive transmission, as in acute stress, lead to impairments in working memory that can be ameliorated by D1 receptor agonist and antagonist treatment, respectively. Iontophoretic investigations of dopamine's influence on the cellular mechanisms of working memory have revealed that moderate D1 blockade can enhance memory fields in primate prefrontal pyramidal neurons while strong blockade abolishes them. The combined behavioral and physiological evidence indicates that there is a normal range of dopamine function in prefrontal cortex that can be described as an "inverted-U" relationship between dopamine transmission and the integrity of working memory. Both in vivo and in vitro studies have demonstrated a role for dopamine in promoting the excitability of prefrontal pyramidal cells and facilitating their N-methyl-d-aspartate inputs, while simultaneously restraining recurrent excitation and facilitating feedforward inhibition. This evidence indicates that there is a fine balance between the synergistic mechanisms of D1 modulation in working memory. Given the critical role of prefrontal function for cognition, it is not surprising that this balancing act is perturbed by both subtle genetic influences and environmental events. Further, there is evidence for an imbalance in these dopaminergic mechanisms in multiple neuropsychiatric disorders, particularly schizophrenia, and in related nonhuman primate models. Elucidating the orchestration of dopamine signaling in key nodes within prefrontal microcircuitry is therefore pivotal for understanding the influence of dopamine transmission on the dynamics of working memory. Here, we explore the hypothesis that the window of optimal dopamine signaling changes on a behavioral time-scale, dependent upon current cognitive demands and local neuronal activity as well as long-term alterations in signaling pathways and gene expression. If we look under the bell-shaped curve of prefrontal dopamine function, it is the relationship between neuromodulation and cognitive function that promises to bridge our knowledge between molecule and mind.     

Differential changes in glutamate concentration in the primate prefrontal cortex during spatial delayed alternation and sensory-guided tasks

Glutamate is a major neurotransmitter in the mammalian brain and glutamatergic neurotransmission in the frontal cortex is indicated to play important roles in cognitive operations. We previously examined changes in extracellular dopamine in the primate frontal cortex in cognitive tasks, and in this paper we extend this to glutamate. We employed, as cognitive tasks, a delayed alternation task where the animal must retain information in working memory, and a sensory-guided task in which there is no working memory requirement but there may be more sensory processing requirements. Using the in vivo microdialysis method, we examined changes in extracellular glutamate concentration in the dorsolateral, arcuate, orbitofrontal, and premotor areas of the primate frontal cortex. Compared to basal rest levels, we observed significant increases in glutamate concentration in dorsolateral and arcuate areas of the prefrontal cortex during the sensory-guided task, but did not find significant changes in any of the frontal areas examined during the delayed alternation task. When glutamate concentration was compared between the delayed alternation and sensory-guided tasks, difference was observed only in the dorsolateral prefrontal cortex, especially in the ventral lip area of the principal sulcus. The results indicate the importance of glutamate in processing sensory information but not in retaining information in working memory in the primate dorsolateral and arcuate prefrontal cortex. We also compared the concentration of glutamate and dopamine in the tasks. We found a double dissociation in the concentration of glutamate and dopamine in the dorsolateral area: there was an increase in glutamate but no change in dopamine during the sensory-guided task, whereas there was an increase in dopamine but no change in glutamate during the delayed alternation task. It is thus suggested that in the primate dorsolateral prefrontal cortex, increased glutamate tone without dopamine increase facilitates sensory-guided task performance, while increased dopamine tone without glutamate increase is beneficial for working memory task performance.     

In vitro binding assays using H nisoxetine and H WIN 35,428 reveal selective effects of gonadectomy and hormone replacement in adult male rats on norepinephrine but not dopamine transporter sites in the cerebral cortex

The prefrontal cortices mediate cognitive functions that critically depend on local dopamine levels. In male rats, many prefrontal tasks where performance is disrupted by changes in dopamine signaling are also impaired by gonadectomy, a manipulation that increases cortical dopamine concentration, prefrontal dopamine axon density and possibly extracellular prefrontal dopamine levels as well. Because these actions could be responsible for the impairing effects of gonadectomy on prefrontal function, the question of how they might arise comes to the fore. Accordingly, the present studies asked whether dopamine levels might be increased via a hormone sensitivity of transporter-mediated dopamine uptake. Specifically, ³H WIN 35,428 and ³H nisoxetine, ligands selective for the dopamine (DAT)- and norepinephrine transporter (NET) respectively, were used in in vitro binding assays to ask whether gonadectomy altered transporter affinity (Kd) and/or binding site number (Bmax) in prefrontal cortex, sensorimotor cortex and/or caudate. Assays performed on tissues dissected from sham-operated, gonadectomized and gonadectomized rats supplemented with testosterone propionate or estradiol for 4 or 28 days revealed no significant group differences or obvious trends in Kd or Bmax for DAT binding or in measures of Bmax for NET binding. However, affinity constants for ³H nisoxetine were found to be significantly higher in sensorimotor and/or prefrontal cortex of rats gonadectomized and gonadectomized and supplemented with estradiol for 4 or 28 days but similar to control in gonadectomized rats given testosterone. Because the NET contributes substantially to extracellular prefrontal dopamine clearance, these androgen-mediated effects could influence prefrontal dopamine levels and might thus be relevant for observed effects of gonadectomy on dopamine-dependent prefrontal behaviors. A hormone sensitivity of the NET could also have bearing on the prefrontal dopamine dysfunction seen in disorders like schizophrenia that disproportionately affect males, whose severity correlates with abnormal testosterone levels, and for which the NET is among suspected sites of pathology.     

Noradrenergic modulation of cognitive function in rat medial prefrontal cortex as measured by attentional set shifting capability

The brain noradrenergic system is thought to facilitate neuronal processes that promote behavioral activation, alertness, and attention. One region in which norepinephrine may exert such effects is the medial prefrontal cortex, which has been implicated in many cognitive functions including arousal, attention, motivation, working memory, response inhibition, and behavioral flexibility. The present study addressed the modulatory influence of noradrenergic neurotransmission in medial prefrontal cortex on cognitive function in rats, as measured by performance in an attentional set shifting task. In experiment 1, we tested effects of increasing and decreasing brain noradrenergic neurotransmission by systemic administration of the alpha2-adrenergic autoreceptor antagonist and agonist drugs, atipamezole and clonidine, respectively. Atipamezole pretreatment significantly improved performance on the stages of the attentional task requiring an extradimensional shift in attention, and those involving stimulus reversals, whereas clonidine had no effect at any stage. In experiment 2, we then tested effects of microinjecting alpha1- or beta-adrenergic receptor antagonists into medial prefrontal cortex on the enhancement of performance on the extradimensional task produced by atipamezole. The atipamezole-induced enhancement of performance on the extradimensional set shifting task was blocked by alpha1-, but not beta-adrenergic receptor antagonists in medial prefrontal cortex. Neither antagonist alone had any effect on extradimensional set shift performance in the absence of atipamezole-induced enhancement. These results indicate that elevating noradrenergic activity at alpha1-receptors in medial prefrontal cortex facilitates cognitive performance of rats in an attentional set-shifting task, which may contribute to the role of norepinephrine in behavioral state changes such as arousal, or to the beneficial cognitive effects of psychotherapeutic drugs that target noradrenergic neurotransmission.     

The effect of dopamine depletion from the caudate nucleus of the common marmoset (Callithrix jacchus) on tests of prefrontal cognitive function

This study examined the effects of depletion of dopamine from the caudate nucleus of the common marmoset (Callithrix jacchus), on tasks sensitive to prefrontal damage (attentional set-shifting and spatial delayed response). There was a marked impairment in performance on the spatial delayed response task, but performance on the attentional set-shifting task was relatively preserved except for an impairment in re-engagement of a previously relevant perceptual dimension. This pattern of impairment is distinct from that seen after excitotoxic lesions of the prefrontal cortex and in patients with Parkinson's disease. Though it is not possible to identify specific cognitive functions that are independent of dopaminergic modulation of the caudate nucleus, due to the partial nature of the lesion, the results do provide insight into those cognitive processes that appear most dependent on caudate dopamine.     

Functions of frontostriatal systems in cognition: comparative neuropsychopharmacological studies in rats, monkeys and humans

A comparative and integrated account is provided of the evidence that implicates frontostriatal systems in neurodegenerative and neuropsychiatric disorders. Specifically, we have made detailed comparisons of performance following basal ganglia disease such as Parkinson's disease, with other informative groups, including Alzheimer's disease, schizophrenia and attention deficit/hyperactivity disorder and structural damage to the frontal lobes themselves. We have reviewed several behavioural paradigms including spatial attention and set-shifting, working memory and decision-making tasks in which optimal performance requires the operation of several cognitive processes that can be successfully dissociated with suitable precision in experimental animals. The role of ascending neurotransmitter systems are analysed from the perspective of different interactions with the prefrontal cortex. In particular, the role of dopamine in attentional control and spatial working memory is surveyed with reference to its deleterious as well as facilitatory effects. Parallels are identified in humans receiving dopaminergic medication, and with monkeys and rats with frontal dopamine manipulations. The effects of serotonergic manipulations are also contrasted with frontal lobe deficits observed in both humans and animals. The main findings are that certain tests of frontal lobe function are very sensitive to several neurocognitive and neuropsychiatric disorders. However, the nature of some of these deficits often differs qualitatively from those produced by frontal lobe lesions, and animal models have been useful in defining various candidate neural systems thus enabling us to translate basic laboratory science to the clinic, as well as in the reverse direction.     

D(1) dopaminergic control of G protein-dependent inward rectifier K(+) (GIRK)-like channel current in pyramidal neurons of the medial prefrontal cortex

Pyramidal neurons of the medial prefrontal cortex (mPFC) exhibit dopamine-dependent prolonged depolarization, which may lead to persistent activity. Persistent activation of prefrontal cortex neurons has been proposed to underlie the working memory process. The purpose of our study was to test the hypothesis that activation of D(1) dopamine receptors leads to inhibition of G protein-dependent inward rectifier K(+) (GIRK) channels, thereby supporting the prolonged depolarization of mPFC pyramidal neurons. Experiments were performed on 3-week-old rats. GIRK-like channel currents recorded from pyramidal neurons showed the following properties at -75 mV: open probability (NPo), 2.5+/-0.3 x 10(-3); mean open time, 0.53+/-0.05 ms; and conductance, 29.9+/-1.6 pS (n=60). The channel currents were strongly inward-rectified. GIRK channel currents were reversibly inhibited by the D(1) agonists SKF 38393 (10 microM) and SKF 81297 (10 microM). This inhibition was abolished by prior application of a dopamine receptor antagonist and by application of the membrane-permeable protein kinase C inhibitors chelerythrine chloride (3 microM) and calphostin C (10 microM). It was also found that the application of D(1) dopamine receptor agonists or GIRK channel inhibitors evoked depolarization of mPFC pyramidal neurons in rats. Moreover, prior application of a GIRK channel blocker eliminated the depolarizing effect of D(1) agonists. We conclude that activation of D(1) dopamine receptors may lead to inhibition of GIRK channel currents that may, in turn, lead to the prolonged depolarization of mPFC pyramidal neurons in juvenile rats.     

Effects of 6-hydroxydopamine lesions of the prefrontal cortex on tyrosine hydroxylase activity in mesolimbic and nigrostriatal dopamine systems.

The effects of prefrontal cortical dopamine depletion on subcortical dopamine function in the rat were examined. 6-Hydroxydopamine lesions of the dopaminergic innervation of the prefrontal cortex did not alter concentrations of dopamine or its metabolite 3,4-dihydroxyphenylacetic acid in either the striatum or nucleus accumbens. Similarly, the activity of the catecholamine biosynthetic enzyme tyrosine hydroxylase in the striatal complex was not changed in animals with prefrontal cortical lesions. Animals sustaining neurotoxic lesions of the prefrontal cortex were challenged with haloperidol in order to activate submaximally tyrosine hydroxylase activity. The magnitude of the haloperidol-induced increase in enzyme activity in the nucleus accumbens was significantly greater in lesioned subjects than in control animals. These data suggest that lesions of the prefrontal cortical dopamine innervation do not result in significant alterations in basal dopaminergic function in the striatal complex. However, lesions of the dopaminergic innervation of the prefrontal cortex significantly increase the responsiveness of mesolimbic dopamine afferents to pharmacological challenge.     

Factors controlling neural activity during delayed-response task performance: testing a memory organization hypothesis of prefrontal function

Understanding the role of prefrontal cortex in delayed-response task performance has been a central focus of neuroimaging research. The first part of this review will emphasize consistent observations of memory-load-related effects on prefrontal cortex activity that have led me and my colleagues to propose a "memory-organization hypothesis" of prefrontal cortex function. The second part examines how predictions of this hypothesis have borne up to empirical testing. The final part of this review suggests that there is important information contained in between-study variance in the anatomical locus and temporal sequence of neural activity. I will examine how subtle variations in task-structure affect subjects' strategies, producing meaningful variability in neuroimaging data. Systematic manipulation of these variables in future research can assist in elucidating the role of prefrontal cortex in delayed response task performance.     

Dopamine modulation of activity of cat sensorimotor cortex neurons during conditioned reflexes

The effects of iontophoretic application of dopamine and selective D1 or D2 dopamine receptor agonists and antagonists on impulse activity of neurons of the deep layers of the sensorimotor cortex of cat were investigated during performance of a conditioned paw movement task. The application of dopamine, Quinpirole (selective D2 receptor agonist) or SKF 38393 (selective D1 receptor agonist) increased both background (P<0.001) and evoked impulse activity (P<0.05 for selective agonists). Selective D2 and D1 receptor antagonists (Sulpiride and SKF 83566, respectively) both increased the latency of neural responses and significantly increased the latency of the conditioned paw movements (P<0.01). These data suggest that during natural physiological functions subcortical dopamine neurons provide facilitation of activity pyramidal neurons of sensorimotor cortex.     

Manipulation of dopamine d1-like receptor activation in the rat medial prefrontal cortex alters stress- and cocaine-induced reinstatement of conditioned place preference behavior

These studies examined the ability of the dopamine D1-like agonist SKF 81297 and D1-like antagonist SCH 23390 in the medial prefrontal cortex to alter the reinstatement of cocaine-induced conditioned place preference behavior. Male Sprague-Dawley rats were fitted with bilateral cannulae over the medial prefrontal cortex and subsequently trained in a conditioned place preference task. Animals were trained in this task using four pairings of cocaine (12 mg/kg, i.p.). Conditioned place preference was demonstrated in all animals, and this behavior was then extinguished over a 5-10-day period before testing for reinstatement. Just prior to reinstatement by immobilization stress or a cocaine priming injection (5 mg/kg, i.p.), a microinjection of the D1-like receptor antagonist SCH 23390 (0.01, 0.1 or 1.0 microg/side), or the D1-like receptor agonist SKF 81297 (0.1, 0.3 or 1.0 microg/side) was given into the medial prefrontal cortex. SCH 23390 blocked both stress- and cocaine-induced reinstatement of conditioned place preference after the two higher doses were administered into the medial prefrontal cortex. The highest dose of SKF 81297 (1.0 microg/side) prevented immobilization stress- but not cocaine-induced reinstatement. The highest dose of these drugs given in the absence of stress or cocaine did not produce reinstatement. The results indicate that immobilization stress given within the place-preference chamber is capable of producing reinstatement of cocaine-seeking behavior. The microinjection studies suggest that D1-like receptor antagonism within the prefrontal cortex is sufficient to block reinstatement by stress and cocaine. Furthermore, the results from D1-like receptor activation in the medial prefrontal cortex point to utilization of different neural pathways for stress- and cocaine-induced reinstatement.     

Age-related spatial working memory impairment is caused by prefrontal cortical dopaminergic dysfunction in rats

There is evidence of prefrontal cortex (PFC)–dependent cognitive deficits, such as working memory impairment, during the normal aging process in humans and animals. Although working memory function and the PFC dopaminergic system are thought to be closely related, the relationship between them in aged subjects remains unclear. The present study was aimed to clarify the involvement of PFC dopaminergic activity in age-related working memory impairment. For this purpose, we examined working memory in young (3-month-old) and aged (24-month-old) rats, using the T-maze delayed alternation task. As a result, delayed alternation performance was impaired in aged rats compared to young rats, indicating age-related working memory impairment. In addition, aged rats showed reduced dopaminergic transmission in the prelimbic cortical region of the PFC, concomitant with attenuated tyrosine hydroxylase activity in the PFC, but not in the ventral tegmental area and substantia nigra, which was evaluated immunohistochemically and enzymatically. Moreover, age-related working memory impairment was improved by direct stimulation of the prelimbic cortical region of the PFC with 10 or 30 ng, but not 100 ng, of a D1 receptor agonist, SKF 81297, indicating that the SKF 81297 response was an inverted “U” pattern. The maximum SKF 81297 response (30 ng) was abolished by a D1 receptor antagonist, SCH 23390. Thus, age-related working memory impairment was through reduced PFC dopaminergic transmission caused by decreased dopamine synthesis in the prefrontal termination region, but not at the site where the projections originate. This finding provides direct evidence showing the involvement of dopaminergic dysfunction in the development of PFC cognitive deficits during the normal aging process and would help to understand the aging physiology and pathology of the brain.     

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.     

Dissociative effects of apomorphine infusions into the medial prefrontal cortex of rats on latent inhibition, prepulse inhibition and amphetamine-induced locomotion

Impaired ability to "gate out" sensory and cognitive information is considered to be a central feature of schizophrenia and is manifested, among others, in disrupted prepulse inhibition and latent inhibition. The present study investigated, in rats, the effects of increasing dopamine receptor activation within the medial prefrontal cortex by local administration of the dopamine receptor agonist apomorphine (9 microg/side) on prepulse inhibition and latent inhibition, as well as on spontaneous and amphetamine-induced activity. Apomorphine infusions decreased spontaneous locomotor activity and blocked amphetamine-induced increase in locomotor activity in the open field, which is in line with the suggestion that dopamine receptor activation in the medial prefrontal cortex inhibits mesolimbic dopamine activity. However, apomorphine infusions induced a disruption of prepulse inhibition, an effect associated with increased dopaminergic activity in the nucleus accumbens, and left the latent inhibition effect intact. While these results support previous evidence that the medial prefrontal cortex is a component of the neural circuitry mediating prepulse inhibition but plays no role in latent inhibition, they show that dopamine receptor activation in the medial prefrontal cortex of the rat produces behavioural outcomes that cannot be explained by postulating a simple reciprocal relationship between the mesocortical and mesolimbic dopamine systems.     

Prefrontal cortical network activity: Opposite effects of psychedelic hallucinogens and D1/D5 dopamine receptor activation

The fine-tuning of network activity provides a modulating influence on how information is processed and interpreted in the brain. Here, we use brain slices of rat prefrontal cortex to study how recurrent network activity is affected by neuromodulators known to alter normal cortical function. We previously determined that glutamate spillover and stimulation of extrasynaptic N-methyl-d-aspartic acid (NMDA) receptors are required to support hallucinogen-induced cortical network activity. Since microdialysis studies suggest that psychedelic hallucinogens and dopamine D1/D5 receptor agonists have opposite effects on extracellular glutamate in prefrontal cortex, we hypothesized that these two families of psychoactive drugs would have opposite effects on cortical network activity. We found that network activity can be enhanced by 2,5-dimethoxy-4-iodoamphetamine (DOI) (a psychedelic hallucinogen that is a partial agonist of 5-HT(2A/2C) receptors) and suppressed by the selective D1/D5 agonist SKF 38393. This suppression could be mimicked by direct activation of adenylyl cyclase with forskolin or by addition of a cAMP analog. These findings are consistent with previous work showing that activation of adenylyl cyclase can upregulate neuronal glutamate transporters, thereby decreasing synaptic spillover of glutamate. Consistent with this hypothesis, a low concentration of the glutamate transporter inhibitor threo-beta-benzoylaspartic acid (TBOA) restored electrically-evoked recurrent activity in the presence of a selective D1/D5 agonist, whereas recurrent activity in the presence of a low level of the GABA(A) antagonist bicuculline was not resistant to suppression by the D1/D5 agonist. The tempering of network UP states by D1/D5 receptor activation may have implications for the proposed use of D1/D5 agonists in the treatment of schizophrenia.     

Dopamine enhances the neuronal activity of spatial short-term memory task in the primate prefrontal cortex

The influence of dopamine and its antagonists on neuronal activity related to the delay period of a delayed response task was examined in the monkey prefrontal cortex. Iontophoretically applied dopamine enhanced the delay-related neuronal activity, while fluphenazine and haloperidol attenuated the activity. Sulpiride had no effect on the activity. The results suggest that dopamine promotes processing of spatial short-term memory by increasing memory-related activity in the primate prefrontal cortex, probably via D1-type dopamine receptor.     

Dopaminergic input is required for increases in serotonin output produced by behavioral activation: an in vivo microdialysis study in rat forebrain.

Previous research has demonstrated that pharmacological stimulation of postsynaptic dopamine D2 receptors produces increases in serotonin output. The present study explored whether this relationship also holds under physiological conditions. Accordingly, we examined the effects of D2 receptor blockade or unilateral dopamine depletion on behaviorally induced increases in extracellular serotonin levels in the corpus striatum and prefrontal cortex of freely moving rats using in vivo microdialysis. Extracellular levels of dopamine and serotonin, as well as behavioral activity, were increased by both mild tail pinch and the light-dark transition. Tail pinch-induced increases in serotonin levels (39+/-3% and 53+/-5% in the corpus striatum and prefrontal cortex, respectively), but not the accompanying behavioral changes, were blocked by local application of the D2 receptor antagonist raclopride (10 microM). D2 receptor blockade also disrupted the positive relationship between striatal serotonin levels and behavioral activity of animals across the light-dark transition (r=0.93 without raclopride, r=0.24 in presence of raclopride). Unilateral 6-hydroxydopamine lesion of the nigrostriatal dopaminergic system also abolished increases in striatal serotonin output induced by both tail pinch and light-dark transition. A negative correlation was observed between the degree of striatal dopamine depletion and tail pinch-induced increases in serotonin efflux (r= - 0.88). Thus, both a local blockade of postsynaptic D2 receptors and striatal dopamine depletion prevented increases in serotonin output that normally accompany behavioral activation. These data indicate that the increases in the forebrain serotonin output produced by two distinct physiological/environmental manipulations appear to be largely dependent upon intact local dopaminergic neurotransmission.