Mesoprefrontal Dopamine Neurons Research Articles

Androgen Influence on Prefrontal Dopamine Systems in Adult Male Rats: Localization of Cognate Intracellular Receptors in Medial Prefrontal Projections to the Ventral Tegmental Area and Effects of Gonadectomy and Hormone Replacement on Glutamate-Stimulated Extracellular Dopamine Level

Although androgens are known to modulate dopamine (DA) systems and DA-dependent behaviors of the male prefrontal cortex (PFC), how this occurs remains unclear. Because relatively few ventral tegmental area (VTA) mesoprefrontal DA neurons contain intracellular androgen receptors (ARs), studies presented here combined retrograde tracing and immunolabeling for AR in male rats to determine whether projections afferent to the VTA might be more AR enriched. Results revealed PFC-to-VTA projections to be substantially AR enriched. Because these projections modulate VTA DA cell firing and PFC DA levels, influence over this pathway could be means whereby androgens modulate PFC DA. To assess the hormone sensitivity of glutamate stimulation of PFC DA tone, additional studies utilized microdialysis/reverse dialysis application of α-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid and N-methyl-D-aspartate receptor subtype-selective antagonists which act locally within the PFC and tegmentally via inhibition or disinhibition of PFC-to-VTA afferents to modulate intracortical DA levels. Here, we compared the effects of these drug challenges in control, gonadectomized, and gonadectomized rats given testosterone or estradiol. This revealed complex effects of gonadectomy on antagonist-stimulated PFC DA levels that together with the anatomical data above suggest that androgen stimulation of PFC DA systems does engage glutamatergic circuitry and perhaps that of the AR-enriched glutamatergic projections from PFC-to-VTA specifically.

Extracellular dopamine and norepinephrine in the developing rat prefrontal cortex: Transient effects of early partial loss of dopamine

Early developmental abnormalities affecting mesocortical dopamine (DA) neurons may result in later functional deficits that play a role in the emergence of psychiatric illness in adolescence/early adulthood. Little is known about the functional maturation of these neurons under either normal or abnormal conditions. In the present study, 6-hydroxydopamine was infused into the rat medial prefrontal cortex (mPFC) on postnatal day (PN) 12–14. On PN30–35, 45–50, and 60–65, mPFC extracellular DA and norepinephrine (NE) concentrations were monitored in intact and lesioned rats using in vivo microdialysis. Extracellular DA and NE concentrations in the intact mPFC remain fairly stable across development; one exception being a trend for acute tailshock-evoked DA concentrations to increase as a function of age. Lesioned rats sustained a persistent (∼50%) decrease in mPFC tissue DA concentrations. Tailshock-evoked increases in mPFC extracellular DA were attenuated in lesioned rats tested on PN30–35, but not PN45–50 or 60–65. Basal and evoked extracellular NE was unaffected in lesioned rats tested at any age, despite a persistent (∼25%) decrease in tissue NE content. Horizontal locomotor activity was also assessed in the present study. Results of previous studies suggest this behavior is modulated by mesoprefrontal DA neurons. Although not significant, acute tailshock- and acute amphetamine-evoked horizontal locomotor activity tended to be attenuated in lesioned rats tested on PN30–35 and augmented in lesioned rats tested on PN60–65. The present data suggest that early partial loss of mesoprefrontal DA nerve terminals, resulting in a persistent decrease in tissue DA concentrations, is unlikely to result in persistent alterations in local DA release.

Neonatal depletion of cortical dopamine: Effects on dopamine turnover and motor behavior in juvenile and adult rats

Abnormal development of mesoprefrontal dopamine (DA) neurons may contribute to the pathophysiology of schizophrenia. Consistent with this hypothesis, DA nerve terminal density is decreased in the cortex of schizophrenic subjects [M. Akil, J.N. Pierri, R.E. Whitehead, C.L. Edgar, C. Mohila, A.R. Sampson, and D.A. Lewis, Lamina-specific alterations in the dopamine innervation of the prefrontal cortex in schizophrenic subjects, Am. J. Psychiatry, 156 (1999) 1580–1589]. This abnormality may be present early in development, giving rise to dysfunction as an individual matures. The present studies examined the effects of early partial loss of medial prefrontal cortex (mPFC) DA on DA turnover and locomotor behavior in juvenile, pubertal, and adult rats (30, 45, and 60 days of age, respectively). Local infusions of 6-hydroxydopamine on postnatal day (PN) 12–14 produced persistent decreases in basal tissue DA concentrations and increases in 3,4-dihydroxyphenylacetic acid (DOPAC):DA ratios in the mPFC. In the nucleus accumbens of lesioned rats, basal DA concentrations were decreased and DOPAC:DA ratios were increased on PN30, but not PN45 or 60. Footshock (30 min at 0.6 mA) increased DOPAC and DOPAC:DA ratios in the mPFC of PN30 and 60 control rats. These effects were attenuated in age-matched rats previously sustaining ∼50% loss of mPFC DA on PN12–14. Footshock did not affect DOPAC:DA ratios in the nucleus accumbens of control or lesioned rats. The lesion also failed to alter basal or stress-evoked motor activity. The present data suggest that a decreased density of mPFC DA nerve terminals occurring early in development results in persistent alterations in basal and stress-evoked activity of mesoprefrontal DA neurons, but not mesoaccumbens DA neurons.

Noradrenergic α-2 agonists have anxiolytic-like actions on stress-related behavior and mesoprefrontal dopamine biochemistry

Clonidine (CLON), an α-2 agonist, has anxiolytic-like actions on the response of mesoprefrontal dopamine (DA) neurons to aversive stimuli in addition to some fear-related behavioral responses. We hypothesized that the anxiolytic-like actions of clonidine could be mimicked by stimulation of α-2 receptors on the mesoprefrontal dopamine neurons. Here, we test this hypothesis using clonidine or guanfacine (GFC), another α-2 agonist, in a model of aversive conditioning that selectively activates the mesoprefrontal dopamine neurons. One day prior to testing with drugs, rats were conditioned to fear a soft tone by pairing it with a footshock. During testing, the animals were subjected to the tones alone after drugs were administered systemically, or by local infusion into the regions containing the cell bodies and terminals of the mesoprefrontal dopamine neurons, namely, the ventral tegmental area (VTA) and the prelimbic (PL) cortex. Systemic administration of guanfacine blocked the increase in immobility in response to the conditioned tone and prevented the stress-associated increase in dopamine turnover in the prelimbic cortex. Systemic clonidine also prevented the stress-associated increase in dopamine turnover but caused sedation preventing behavioral measures. Guanfacine was then used in all local injection studies. The local application of guanfacine into either the prelimbic cortex or the ventral tegmental area did not prevent the conditioned fear-induced increase in dopamine turnover or the increase in immobility in response to the conditioned tones. We conclude that the anxiolytic-like actions of α-2 agonists are not due to binding to α-2 receptors on the stress-sensitive mesoprefrontal dopamine neurons.

Selective prefrontal cortex inputs to dopamine cells: implications for schizophrenia

Dopamine (DA) neurons in the substantia nigra (SN) and ventral tegmental area (VTA) form several projection systems with diverse functions, such as motor planning through the striatum, reward seeking via the nucleus accumbens (NAc), and cognitive control through the prefrontal cortex (PFC). Disruptions in DA cell activity profoundly impair these functions and contribute to serious clinical conditions such as Parkinson's disease and schizophrenia. DA neurons have been extensively investigated in studies detailing their anatomy, physiology, and neurochemical regulation. Moreoever, recordings from behaving animals suggest that phasic changes in DA cell firing signal expectancy or attentional shifts associated with approach/avoidance behavior. These ideas raise interesting questions regarding how DA neurons are regulated to produce such phasic signals. For example, it is not yet known how different classes of DA projection neurons are regulated by specific inputs. In the first study of its kind within the VTA, our laboratory recently demonstrated that excitatory inputs from the PFC synapse selectively onto DA neurons that project back to the PFC but not onto DA cells that project to the NAc. These findings may explain some of the unique functional properties of mesoprefrontal DA neurons. Moreover, the results are important for understanding the pathophysiology of mental disorders such as schizophrenia.

Target-specific glutamatergic regulation of dopamine neurons in the ventral tegmental area.

Dopamine (DA) neurons in the ventral tegmental area (VTA) are thought to play a critical role in affective, motivational, and cognitive functioning. There are fundamental target-specific differences in the functional characteristics of subsets of these neurons. For example, DA afferents to the prefrontal cortex (PFC) have a higher firing and transmitter turnover rate and are more responsive to some pharmacological and environmental stimuli than DA projections to the nucleus accumbens (NAc). These functional differences may be attributed in part to differences in tonic regulation by glutamate. The present study provides evidence for this mechanism: In freely moving animals, blockade of basal glutamatergic activity in the VTA by the selective alpha-amino-3-hydroxy-5-methyl-4-isoxazole propionic acid (AMPA)/kainate antagonist LY293558 produced an increase in DA release in the NAc while significantly decreasing DA release in the PFC. These data support an AMPA receptor-mediated tonic inhibitory regulation of mesoaccumbens neurons and a tonic excitatory regulation of mesoprefrontal DA neurons. This differential regulation may result in target-specific effects on the basal output of DA neurons and on the regulatory influence of voltage-gated NMDA receptors in response to phasic activation by behaviorally relevant stimuli.

TMT, a predator odor, elevates mesoprefrontal dopamine metabolic activity and disrupts short-term working memory in the rat

Working memory has been proposed to require the proper functioning of the medial prefrontal cortex and its dopaminergic innervation. The dopaminergic input to the medial prefrontal cortex has been demonstrated to be sensitive to physical and psychological stress. In this report, we demonstrate that a brief exposure to 2,5-dihydro-2,4,5-trimethylthiazoline (TMT), an odor derived from a predator of the rat, the fox, resulted in elevated dopamine metabolism in the medial prefrontal cortex and elevated serum corticosterone. We tested the effects of this olfactory stress on working memory using a spontaneous, delayed, non-matching-to-sample task using object recognition methods. Rats were exposed to one set of objects and, after a delay of 1, 15 or 60 min, later demonstrated a robust working memory of the familiar object compared to a novel object. When rats were exposed to TMT during the 15-min delay, working memory was disrupted without altering exploratory behavior. We conclude from these studies that (1) TMT selectively activates mesoprefrontal dopamine neurons, (2) TMT exposure can disrupt working memory and (3) this disruption in working memory is not due to an overall suppression of exploratory behavior but may involve altered mesoprefrontal dopaminergic activity.

Dissociation of Haloperidol, Clozapine, and Olanzapine Effects on Electrical Activity of Mesocortical Dopamine Neurons and Dopamine Release in the Prefrontal Cortex

The aim of the present study was to compare the effects of the typical antipsychotic haloperidol and the atypical antipsychotics clozapine and olanzapine on both extracellular dopamine (DA) levels in the medial prefrontal cortex (mPFC) as well as electrical activity of mesoprefrontal DA (mPFC-DA) neurons. Extracellular single unit recordings and microdialysis experiments were carried out in different groups of chloral hydrate anesthetised rats under identical experimental conditions. Intravenous administration of haloperidol, clozapine, and olanzapine increased the firing rate and burst activity of antidromically-identified mPFC-DA neurons; maximal increase in firing rate of approximately 140, 155, and 70 %, was produced by haloperidol, clozapine, and olanzapine at doses of 0.2, 2.5, and 1 mg/kg, i.v., respectively. Intravenous administration of the same doses increased extracellular DA levels in mPFC by 20%, 190%, and 70%, respectively. Moreover, while haloperidol and olanzapine increased extracellular levels of the deaminated DA metabolite DOPAC, by 60% and 40%, respectively, clozapine was totally ineffective. The D1 receptor antagonist SCH 23390 modified neither DA output nor neuronal firing. To determine whether the effect of the three antipsychotics on DA release might depend on a direct action on the mPFC, rats were perfused locally via inverse dialysis in the mPFC at concentrations ranging from 10−6 to 10−4M. While clozapine and olanzapine increased extracellular DA concentrations by up to 400% of basal level, haloperidol was totally ineffective. The results obtained from this study indicate that the rank potency of the three antipsychotics in stimulating the firing rate of DA neurons projecting to mPFC, correlates with their affinity for D2 receptors and doses used clinically. On the other hand, their stimulating effect on DA release does not correlate with their effect on neuronal firing but depends on a direct action on the mPFC.

Divergent effects of putative anxiolytics on stress-induced Fos expression in the mesoprefrontal system of the rat

Previously, we reported that R(+)HA-966, a weak partial agonist for the glycine/NMDA receptor, and guanfacine, a noradrenergic α2 agonist, have anxiolytic-like actions on the biochemical activation of the mesoprefrontal dopamine neurons and fear-induced behaviors. Here, we examined these two putative anxiolytic agents, both with primary actions independent of GABAergic systems, for their ability to alter stress-induced Fos-like immunoreactivity in the mesoprefrontal cortex and in tyrosine hydroxylase-stained, presumed dopaminergic, neurons in the ventral tegmental area. The benzodiazepine agonist, lorazepam, and partial agonist, bretazenil, were also tested in this footshock paradigm [10 × 0.5 sec, 0.8 mA paired with a 5-sec tone]. In saline-treated rats, footshock resulted in an increase in Fos-li in the prelimbic and infralimbic cortices and tyrosine hydroxylase-labeled cells in the ventral tegmental area. Treatment with lorazepam or bretazenil prevented the stress-induced activation in Fos-li nuclei in all regions of the medial prefrontal cortex and in dopaminergic neurons in the ventral tegmental area. In contrast, the actions of the novel anxiolytic-like agents on stress-induced Fos-li were different than those observed with benzodiazepine agonists. Both putative anxiolytics, R(+)HA-966 and guanfacine, did not reduce, but significantly enhanced the stress-induced Fos-li in the prelimbic region of the medial prefrontal cortex. Additionally, treatment with R(+)HA-966 completely blocked, while guanfacine attenuated, the stress-induced increase in the number of Fos-li, TH-li cells in the ventral tegmental area. These results indicate that the putative anxiolytics, R(+)HA-966 and guanfacine, have actions on the stress-sensitive mesoprefrontal system which appear distinct from those of traditional anxiolytics. Synapse 36:143–154, 2000. © 2000 Wiley-Liss, Inc.

Chronic clozapine, but not haloperidol, alters the response of mesoprefrontal dopamine neurons to stress and clozapine challenges in rats.

Previously, we demonstrated that serotonin-lesioned rats had an enhanced mesoprefrontal dopaminergic response to restraint stress. This study attempted to extend our knowledge regarding this serotonin/dopamine interaction by seeing if suppression of serotonin metabolism by chronic administration of the atypical antipsychotic, clozapine, would have similar effects. Both typical and atypical neuroleptics require chronic administration in humans before antipsychotic activity is seen. Rats treated for 21 days with clozapine or haloperidol, a typical antipsychotic without significant binding affinity for serotonergic receptors, showed lowered basal dopamine metabolism in the medial prefrontal cortex, the nucleus accumbens, and the striatum, as expected. Basal serotonin metabolism in the prefrontal cortex was also lowered by clozapine treatment, but not haloperidol. One of two challenges were given to chronically treated rats: 30 min of restraint stress or an acute challenge of clozapine. When corrected for baseline differences, both challenges significantly elevated dopamine metabolism in the prefrontal cortex of the clozapine group more than the saline or haloperidol groups. No hyperresponsiveness was seen with serotonin metabolism in the prefrontal cortex or either dopamine or serotonin metabolism in the nucleus accumbens in clozapine-treated, challenged rats. Additionally, this augmentation of the dopaminergic stress response was not seen with a single, acute administration of clozapine. The significance of the clozapine-induced hyperresponsiveness of the mesoprefrontal dopamine system is discussed with regard to clinical efficacy of clozapine.

Chronic clozapine, but not haloperidol, alters the response of mesoprefrontal dopamine neurons to stress and clozapine challenges in rats

Previously, we demonstrated that serotonin-lesioned rats had an enhanced mesoprefrontal dopaminergic response to restraint stress. This study attempted to extend our knowledge regarding this serotonin/dopamine interaction by seeing if suppression of serotonin metabolism by chronic administration of the atypical antipsychotic, clozapine, would have similar effects. Both typical and atypical neuroleptics require chronic administration in humans before antipsychotic activity is seen. Rats treated for 21 days with clozapine or haloperidol, a typical antipsychotic without significant binding affinity for serotonergic receptors, showed lowered basal dopamine metabolism in the medial prefrontal cortex, the nucleus accumbens, and the striatum, as expected. Basal serotonin metabolism in the prefrontal cortex was also lowered by clozapine treatment, but not haloperidol. One of two challenges were given to chronically treated rats: 30 min of restraint stress or an acute challenge of clozapine. When corrected for baseline differences, both challenges significantly elevated dopamine metabolism in the prefrontal cortex of the clozapine group more than the saline or haloperidol groups. No hyperresponsiveness was seen with serotonin metabolism in the prefrontal cortex or either dopamine or serotonin metabolism in the nucleus accumbens in clozapine-treated, challenged rats. Additionally, this augmentation of the dopaminergic stress response was not seen with a single, acute administration of clozapine. The significance of the clozapine-induced hyperresponsiveness of the mesoprefrontal dopamine system is discussed with regard to clinical efficacy of clozapine. Synapse 34:28–35, 1999. © 1999 Wiley-Liss, Inc.

Effects of partial dopamine loss in the medial prefrontal cortex on local baseline and stress-evoked extracellular dopamine concentrations

A reduction in the activity of mesoprefrontal dopamine neurons has been suggested to play a role in the pathophysiology of schizophrenia. Indeed, a recent study indicates that the density of tyrosine hydroxylase-immunoreactive axons is decreased in the deep layers of the prefrontal cortex of schizophrenic subjects [Akil et al., (1999) Am. J. Psychiatry, in press]. To determine the impact of partial loss of prefrontal dopamine axons on the activity of the remaining dopamine axons, we examined the effects of 6-hydroxydopamine lesions of the medial prefrontal cortex on local extracellular dopamine concentrations in the rat. In rats sustaining an average 63% loss of tyrosine hydroxylase-immunoreactive axons and no loss of dopamine-β-hydroxylase-immunoreactive axons in the medial prefrontal cortex (smaller lesion), the baseline extracellular dopamine concentration was reduced by 63±9%. Thirty minutes of tail pressure increased extracellular dopamine in the medial prefrontal cortex by a maximum of 1.28±0.28 pg in control rats, but only 0.74±0.18 pg in rats with smaller lesions. In rats sustaining an average 80% loss of tyrosine hydroxylase-immunoreactive axons and 25% loss of dopamine-β-hydroxylase-immunoreactive axons (larger lesion), the baseline extracellular dopamine concentration in the medial prefrontal cortex did not differ from control values. In addition, the maximum stress-evoked increase in dopamine concentration was also similar to that observed in control rats (+1.04±0.28 pg). The stress-induced increase in extracellular dopamine in the medial prefrontal cortex of rats sustaining smaller and larger lesions may occur in the absence of a corresponding increase in dopamine synthesis in mesoprefrontal dopamine neurons. This proposal is supported by our observation that stress did not alter tissue or extracellular 3,4-dihydroxyphenylacetic acid concentrations in the medial prefrontal cortex of lesioned rats. These data suggest that moderate loss of tyrosine hydroxylase-immunoreactive axons in the prefrontal cortex is sufficient to reduce extracellular dopamine concentrations in this brain region. In addition, a further reduction in tyrosine hydroxylase-immunoreactive axons in the medial prefrontal cortex, combined with the loss of dopamine-β-hydroxylase-immunoreactive axons, results in normal extracellular dopamine concentrations in this area. We propose that the latter effect is due to increased neurochemical activity of remaining mesoprefrontal dopamine axons and/or decreased clearance of extracellular dopamine due to loss of both dopamine and norepinephrine transporters.

The role of mesoprefrontal dopamine neurons in the acquisition and expression of conditioned fear in the rat

The mesoprefrontal dopamine neurons are sensitive to physical, pharmacological and psychological stressors. In this report, the role of these neurons in the response to classical fear conditioning was investigated. 6-Hydroxydopamine lesions to the medial prefrontal cortex reduced dopamine levels to about 13% of controls but did not alter behavior during the acquisition of fear conditioning. As expected, conditioned fear increased dopamine metabolism (3,4-dihydroxyphenylacetic acid/dopamine ratio) in the nucleus accumbens in sham-lesion rats. The medial prefrontal 6-hydroxydopamine lesions did not alter this effect. During the expression, however, lesioned rats demonstrated a delayed extinction of the conditioned response without an overall increase in the initial conditioned response. This effect was consistent in rats receiving 6-hydroxydopamine lesions before or after the acquisition period. The calculated rates of extinction showed that the 6-hydroxydopamine lesioned rats had a reduced rate of extinction, but not acquisition, of fear conditioning. The results presented in this manuscript indicate that the mesoprefrontal dopamine neurons are involved in co-ordinating the normal extinction of a fear response but do not alter the acquisition of fearful behaviors. These data are consistent with the conclusion that the mesoprefrontal dopamine neurons are involved in maintaining the animal's response adaptability with regards to stress-related changes in the external environment.

Biochemical and behavioral anxiolytic-like effects of R(+)HA-966 at the level of the ventral tegmental area in rats.

R(+) HA-966, a weak partial agonist at the glycine/NMDA receptor complex, has been shown to have anxiolytic-like actions on restraint stress-induced mesoprefrontal dopamine metabolism. This study investigates the putative anxiolytic, R(+) HA-966, applied locally at the level of the mesocorticolimbic dopamine cell bodies in the ventral tegmental area (VTA), on the acquisition and expression of conditioned fear. Ten to 14 days after cannula implantation, rats were subjected to the acquisition session (10x5 s tone paired with 0.5 s, 0.8 mA footshock) followed about 24 h later by the expression session (ten tones only) of a conditioned fear protocol. Rats were treated with R(+) HA-966 (15 microg/VTA) or saline before either the acquisition or expression sessions. Other rats were injected with saline or R(+) HA-966 (10 microg/side), intra-medial prefrontal cortex, on the expression day. R(+)HA-966, intra-VTA, prevented stress-induced changes in mesoprefrontal, but not mesoaccumbal, dopamine metabolism and was associated with a reduction in fearful responses to physical (footshock) and psychological (conditioned fear) stressors. Additionally, rats treated with R(+)HA-966 intra-VTA before the acquisition session were less fearful at the beginning of the expression session. Local injection of R(+)HA-966 into medial prefrontal cortex did not have anxiolytic-like behavioral or biochemical actions but diminished the expression of exploratory behavior in non-stress, control rats. These studies indicate that the stress-induced activation of the mesoprefrontal dopamine neurons is necessary for the normal expression of fearful behaviors.

Mesoprefrontal dopaminergic neurons: Can tyrosine availability influence their functions?

The dopamine (DA) neurons projecting to the prefrontal cortex (PFC) are thought to be involved in working memory, stress response, and the pathogenesis of schizophrenia. In this commentary, we review the current evidence supporting a precursor tyrosine dependence of these mesoprefrondal DN neurons. Several studies in rats employing different experimental paradigms [i.e. experimental diabetes and early-treated phenylketonuria (PKU) model]have shown that reduced tyrosine levels in brain can affect markedly the physiology and functions of these DA neurons. However, supplemental tyrosine is effective in enhancing functional transmitter outflow from mesoprefrontal DA neurons only under conditions where their physiological activity is enhanced and DA synthesis and release are uncoupled from intrinsic regulatory controls. Recent studies in Humans have also suggested that variations in brain tyrosine levels can affect significantly higher cortical functions subserved by the PFC. In early-treated PKU patients with mildly reduced tyrosine levels, marked impairments in cognitive functions dependent on the dorsolateral PFC could be detected. In drugtreated schizophrenic patients, supplemental tyrosine was shown to have a disruptive effects on the smoothpursuit eye movement performance task. Furthermore, tyrosine administration was effective in restoring impaired working memory in humans following a cold stress paradigm, as assessed by a computer-based delayed matchingto-sample memory task. These human studies, together with the current evidence obtained from animal experiments, suggest that the functions of the mesoprefrontal DA neurons can, under certain circumstances, be readily influenced by the availability of the precursor tyrosine.

Dysregulation of Mesoprefrontal Dopamine Neurons Induced by Acute and Repeated Phencyclidine Administration in the Nonhuman Primate: Implications for Schizophrenia

Publisher Summary Phencyclidine (PCP) induces several distinct behavioral effects in humans and animals that appear to represent schizophrenia-like symptomatology. In humans, acute PCP exposure can induce both positive and negative symptoms of schizophrenia. In contrast, repeated exposure to PCP in humans can lead to enduring presentation of both negative and positive symptoms of schizophrenia. Thus, repeated PCP administration may induce neurobiological defects that mimic those present in the brain of patients with schizophrenia. This chapter discusses some of the recent studies on the effects of acute and repeated PCP administration on the rodent and nonhuman primate dopamine (DA) systems and how these neurobiological effects may underlie the psychotomimetic properties of PCP. The chapter also evaluates the relevance of DAergic dysfunction for the hypoglutamatergic and neuropathological hypotheses of PCP's effects. In the primate, acute PCP administration causes a selective activation of DA metabolism in the frontal cortex, while sparing subcortical DA systems. It is suggested that activation of DA systems by PCP may be involved in the development of neuropathology after acute PCP administration. Taken together, these studies indicate that repeated PCP administration may model the cognitive dysfunction of schizophrenia and suggest that this dysfunction may be because of an inhibition of DAergic function in the PFC. Further, this paradigm may represent a step forward in biological psychiatric research by offering a tool for evaluating the pathophysiology of the deficits of schizophrenia and a mechanism for the evaluation of novel agents that may be able to ameliorate the typically treatment-refractory negative symptoms in this debilitating disorders.

The role of mesoprefrontal dopamine neurons in stress.

While several catecholaminergic systems are activated by stressful stimuli, the mesoprefrontal dopamine (DA) system appears to be particularly vulnerable to stress. Low intensity stressors that do not produce detectable effects in most ascending catecholaminergic systems activate mesoprefrontal DA neurons. Mesoprefrontal DA neurons are unique in that they lack or have decreased densities of specific autoreceptors affecting autoregulatory capabilities, which could contribute to the fact that mesoprefrontal DA neurons exhibit increased rates of burst firing and DA turnover relative to other midbrain dopaminergic projections. In addition, mesoprefrontal DA neurons are uniquely modulated by a number of chemically distinct afferent influences including gamma-aminobutyric acid (GABA), serotonin, excitatory amino acid, substance P, opiate, and noradrenergic systems. Any or all of these factors could contribute to the selective activation of mesoprefrontal DA neurons following exposure to low intensity stressors. The present review summarizes the possible mechanisms by which mesoprefrontal DA neurons are preferentially activated by stress. The operational significance of this unique neurochemical response to stress is discussed in terms of a possible coping versus anxiety function. Also discussed are the ramifications of a dysfunction of this system with respect to stress-related or exacerbated disorders such as post-traumatic stress disorder and schizophrenia.

Blocking effects of ethanol on stress-induced activation of rat mesoprefrontal dopamine neurons

We investigated the effects of ethanol on stress-induced activation of the brain dopamine (DA) systems in rats. Ethanol (0.5 and 1.0 g/kg) was injected IP 25 min before sacrifice (5 min before 20-min immobilization stress). Ethanol treatment by itself did not affect the levels of either DA or its major metabolite, 3,4-dihydroxyphenylacetic acid (DOPAC), in the mesoprefrontal cortex, cingulate cortex, olfactory tubercle, or caudate putamen. Immobilization stress for 20 min caused increases in DOPAC levels in the prefrontal cortex (160% of control) and cingulate cortex (135% of control), but not in the olfactory tubercle or caudate putamen. The stress had no effects on DA levels in any of the four brain regions studied. Pretreatment with ethanol blocked, in a dose-dependent manner, the stress-induced increases in DOPAC levels in the mesoprefrontal cortex. The present data suggest that ethanol exhibits a blocking effect on stress-induced activation of the mesoprefrontal DA neurons. This blocking effect may be related to the anxiolytic action of ethanol.

Evoked extracellular dopamine in vivo in the medial prefrontal cortex.

The measurement of evoked extracellular dopamine in the medial prefrontal cortex by using fast-scan cyclic voltammetry with carbon-fiber microelectrodes was established and release characteristics of mesoprefrontal dopamine neurons were examined in vivo in anesthetized rats. Despite the sparse dopaminergic innervation and the presence of more dense noradrenergic and serotonergic innervations overall in the medial prefrontal cortex, the measurement of extracellular dopamine was achieved by selective recording in dopamine-rich terminal fields and selective activation of ascending dopamine neurons. This was confirmed by electrochemical, pharmacological, and anatomical evidence. An increased release capacity for mesoprefrontal dopamine neurons was also demonstrated by the slower decay of the evoked dopamine response after inhibition of catecholamine synthesis and the maintenance of the evoked dopamine response at higher levels in the medial prefrontal cortex compared with the striatum during supraphysiological stimulation.

Psychological stress increases dopamine turnover selectively in mesoprefrontal dopamine neurons of rats: reversal by diazepam

The effects of psychological stress on catecholamine and indoleamine metabolism were examined in various brain regions of rats. Psychologically stressed rats were exposed to emotional responses of foot-shocked rats, but were themselves prevented from receiving foot-shock. Psychological stress for 30 min resulted in significant increases of both 3,4-dihydroxyphenylacetic acid (DOPAC) and homovanillic acid (HVA) levels in the medial prefrontal cortex (MPFC), but not in other dopamine (DA) terminal fields. The levels of noradrenaline (NA), serotonin (5-HT) and 5-hydroxyindoleacetic acid (5-HIAA) were unaffected in all brain regions examined after 30 min of psychological stress. A small but significant increase of DOPAC levels in the ventral tegmental area (VTA) was observed after a shorter (10 min) duration of stress. Moreover, an increase of DOPAC levels in the MPFC 30 min after psychological stress was attenuated by diazepam (5 mg/kg), and this attenuating effect was antagonized by Ro 15-1788 (15 mg/kg). These results suggest that mesoprefrontal DA neurons are selectively activated by psychological stress, and that the activation of the A10 cell body site (VTA) may precede that of the terminal field (MPFC). Moreover, diazepam was found to possess an inhibitory effect on the activation of mesoprefrontal DA neurons induced by psychological stress, and this effect may be partly mediated by benzodiazepine (BZD) receptors and implicated in the specific anxiolytic action of BZDs.