Pharmacology of dopamine neurons innervating the prefrontal, cingulate and piriform cortices

Dopaminergic innervation of the primary visual cortex in the rat, and some correlations with human cortex

Dopaminergic terminals have been identified in the primary visual cortex with three techniques; immunocytochemistry with an anti-dopamine antiserum, retrograde axonal transport techniques using unconjugated wheat germ agglutinin and HPLC determination of catecholamines and metabolites in microdissected sub-regions of occipital cortex in the rat. The results demonstrate a specific dopaminergic innervation, arising from the ventral tegmental area, which is found mainly in laminae VI and V, but with minor innervation also in lamina I. Dopaminergic innervation to adjacent cortical regions is also described. Neurochemical data from post-mortem human material suggests that a similar innervation exists in man. An analysis of the distribution of dopaminergic fibres in relation to the known connections and possible functions of the deep laminae of visual cortex suggests that dopaminergic axons may participate in the corticofugal control of visual afferent pathways.

Mesolimbic and mesocortical dopamine activation induced by phencyclidine: contrasting pattern to striatal response

The effects of acute administration of phencyclidine, an indirect dopamine agonist, on biochemical indices of dopaminergic activation were examined in mesocortical, mesolimbic and nigrostriatal regions of the rat. High doses (10 mg/kg) of phencyclidine resulted in a marked increase in levels of the dopamine metabolites 3,4-dihydroxyphenylacetic acid and homovanillic acid in all mesolimbic and mesocortical sites examined, as well as in the ventral tegmental area, source of the dopaminergic innervation of mesolimbic/cortical sites. In contrast, levels of both metabolites decreased in the striatum and tended to decrease in the substantia nigra, source of the striatal dopaminergic innervation. The metabolite response to phencyclidine was dose-related. These data indicate that the mesolimbic and mesocortical dopaminergic neurons are activated by phencyclidine. Since the firing rate of both A10 (ventral tegmental area) and A9 (substantia nigra) dopamine neurons has previously been shown to be increased by phencyclidine, these data suggest that phencyclidine results in a differential regulation of presynaptic release of dopamine in mesolimbic/cortical as opposed to nigrostriatal dopaminergic regions.

D-2 dopamine-receptors regulate the release of [3H]dopamine in rat cortical regions showing dopamine immunoreactive fibers

Using an antibody raised against dopamine the occurrence of dopamine-containing fibers was demonstrated in the prefrontal cortex, anterior cingulate cortex, parietal neocortex, piriform cortex and entorhinal cortex. In extracts of these cortical regions significant amounts of dopamine, although approximately a 100-fold less than in the neostriatum or nucleus accumbens, were detected with high performance liquid chromatography. The release of [3H]dopamine from slices of all these cortical regions was studied in vitro in a superfusion system and desipramine was used to prevent the uptake of [3H]dopamine in noradrenergic nerve terminals. It appeared that the electrically evoked release of radioactivity was inhibited by drugs stimulating D-2 dopamine-receptors in all the regions studied. Cation-exchange column chromatography revealed that the radioactivity released consisted predominantly of [3H]dopamine, indicating that D-2 receptors mediate the inhibition of the release of [3H]dopamine from dopaminergic nerve terminals. Likewise, in the neostriatum as well as in the nucleus accumbens D-2 receptor stimulation inhibits the release of [3H]dopamine. Therefore it is our conclusion that D-2 receptors regulate the release of dopamine from dopaminergic neurons originating in the ventral tegmental area as well as in the substantia nigra.

The agranular insular cortex: a site of unusually high dopamine utilisation

Dopamine (DA) utilisation (expressed as homovanillic acid:DA) was compared in the medial prefrontal cortex (FCx), the agranular insular cortex (AgCx), the caudate-putamen (medial, CPM and lateral, CPL divisions) and the nucleus accumbens (NAc). DA utilisation in these regions decreased in the order AgCx greater than FCx greater than CPM, CPL, NAc, whilst the concentration of DA decreased in the reverse order. Thus, although fewer DA neurones appear to innervate AgCx compared with FCx, the rate of DA utilisation/release is much greater in AgCx. It is suggested that this apparently more marked activity in DA neurones innervating AgCx may reflect a relative lack of autoreceptor control.

Opiate actions on mesocortical dopamine metabolism in the rat

The actions of parenteral morphine were examined with regard to dopamine metabolism in the mesocortical dopaminergic pathways of the rat. The effects of morphine on dopamine metabolism in the prefrontal, cingulate, pyriform and entorhinal cortices were compared with the actions of morphine on the metabolism of dopamine in the striatum and olfactory tubercle. In all tissues, except the entorhinal cortex, morphine significantly elevated the dopamine metabolites dihydroxphenylacetic acid and homovanillic acid. These data, along with previous studies of various pharmacological agents, clearly indicate that the mesocortical dopaminergic projections possess unique opioid and non-opioid regulatory inputs.

Dopamine autoreceptors modulate dopamine release from the prefrontal cortex

Electrical stimulation (at 0.3, 1, or 10 Hz, 120 pulses each) produced a calcium-dependent overflow of radioactivity from slices of the rabbit prefrontal cortex preloaded with [3H]3,4-dihydroxyphenylethylamine ([3H]DA, [3H]dopamine) in the presence of desipramine. Flat frequency-release curves were observed. Apomorphine and LY-171555 inhibited in a concentration-dependent fashion the evoked overflow of DA, an effect antagonized by haloperidol. Stimulation frequencies comparable to normal firing rates of mesocortical neurons (10 Hz) drastically reduced apomorphine-induced inhibition of DA overflow. Haloperidol produced greater facilitation of DA overflow at 10 than at 1 Hz. Nomifensine, a neuronal uptake inhibitor, enhanced DA overflow. These results indicate that mesocortical DA neurons projecting to the prefrontal cortex have release modulatory autoreceptors of the D2 subtype.

Regional brain homovanillic acid following delta 9-tetrahydrocannabinol and cocaine

delta 9-Tetrahydrocannabinol (10 mg/kg) increased homovanillic acid in rat prefrontal cortex and olfactory tubercle. This dose did not affect homovanillic acid in the caudate. Higher doses increased homovanillic acid in all 3 regions. Cocaine (20, 30, or 50 mg/kg) did not affect homovanillic acid in any of these brain regions.

Modulation of terminal excitability of mesolimbic dopaminergic neurons by D-amphetamine and haloperidol

Electrophysiological techniques were used to study the changes in the terminal excitability of mesolimbic DA and non-DA neurons following the infusion of D-amphetamine (D-AMP) and haloperidol (HAL) into the nucleus accumbens (NAc) of rats. The amount of current needed to evoke antidromic spikes by electrical stimulation of the NAc was used as an index of the excitability of axon terminals of these neurons. The excitability of DA neurons was decreased by D-AMP and increased by HAL. In addition, the effect produced by D-AMP was reversed by HAL. By contrast, these drugs either induced an opposite effect or were ineffective in inducing changes on the excitability of nerve terminals of mesolimbic non-DA neurons. Infusion of the vehicle or saline produced no effect. D-AMP and HAL were still effective in modulating the excitability of mesolimbic DA nerve terminals after the destruction of NAc neurons by ibotenic acid. The results suggest that the effects seen after D-AMP and HAL are mediated primarily by DA autoreceptors. It is likely that the increase in the current needed for evoking antidromic spikes after infusion of D-AMP into the terminal region is the consequence of DA autoreceptor-mediated hyperpolarization of terminal membranes. On the other hand, HAL could exert its actions by blocking autoreceptor-mediated hyperpolarization.

In vivo electrochemical detection of 5-hydroxyindoles in rat cerebral cortex and spinal cord: differential effects of p-chloroamphetamine, probenecid and clorgyline

Differential pulse voltammetry associated with carbon fiber microelectrodes was used to detect the 300 mV signal which is known to reflect the concentration of 5-hydroxyindoles in the spinal cord and cerebral neocortex of rats anesthetized with urethane or chloral hydrate. The intraperitoneal injection of p-chloroamphetamine resulted in an increase in the amplitude of the signal in the neocortex but not in the spinal cord. Administration of clorgyline did not consistently modify the signal monitored in the neocortex whereas it decreased in the spinal cord. Probenecid induced a larger increase in 5-hydroxyindoles in the neocortex than in the spinal cord. These results demonstrate that different parts of the serotonergic system might be differentially sensitive to drugs affecting serotonin metabolism.

Release of dopamine from mesencephalic neurons in aggregate cultures: influence of target and non-target cells

Spontaneous release of [3H]dopamine (DA) was observed from reaggregates of dissociated cells from fetal rostral mesencephalic tegmentum (RMT) containing DA neurons cocultured with their axonal target cells from striatum (CS) or frontal cortex (FCx), or with non-target cells from occipital cortex (OCx), or tectum. Such release increased in response to 50 mM K+. Tetrodotoxin (TTX) suppressed the spontaneous release from RMT-CS and RMT-FCx reaggregates by 42%; from RMT-tectum reaggregates by 24%, and did not significantly inhibit the release from RMT-OCx cocultures. Since TTX blocks spontaneous neuronal activity, these results suggest that the presence of axonal target cells enhances the activity of the dopamine neurons. DA neurons within RMT-FCx reaggregates released significantly more [3H]DA in response to 50 mM K+ than in RMT-CS cocultures. This result is in accord with the findings in vivo that inhibitory feedback mechanisms on DA release, present in the striatum, are lacking in the frontal cortex.

Evidence for the absence of impulse-regulating somatodendritic and synthesis-modulating nerve terminal autoreceptors on subpopulations of mesocortical dopamine neurons

Electrophysiological and biochemical techniques were used to study midbrain dopamine systems. In the electrophysiological studies, projection areas of individual dopaminergic cells were identified by antidromic activation. Dopamine cells which innervate the piriform cortex and those that innervate the caudate nucleus demonstrated their usual dose-dependent inhibitory response to both the intravenous administration of the direct-acting dopamine agonist apomorphine and the microiontophoretic application of dopamine. In contrast, the firing rate of dopamine neurons which project to the prefrontal cortex and of those terminating in the cingulate cortex was not altered by either the intravenous administration of low to moderate doses of apomorphine or microiontophoretically applied dopamine. The mean basal discharge rate and degree of burst firing was also different between these subgroups of midbrain dopaminergic neurons. Mesoprefrontal and mesocingulate dopamine neurons had mean firing rates of 9.3 and 5.9 spikes/s respectively, and showed intense burst activity. Mesopiriform and nigrostriatal dopamine cells had discharge rates of 4.3 and 3.1 spikes/s and displayed only moderate bursting. The dopaminergic nature of those mesocortical neurons insensitive to apomorphine and dopamine was confirmed using combined intracellular recording and catecholamine histofluorescence techniques. Thus, after the intracellular injection of colchicine and subsequent processing for glyoxylic acid-induced histofluorescence, the injected cells could be identified by their brighter fluorescences compared to the surrounding, normally fluorescing, non-injected dopamine neurons. Using biochemical techniques, subgroups of midbrain dopaminergic systems were again found to differ. The administration of gamma-butyrolactone increased dopamine levels in all areas sampled (prefrontal, cingulate and piriform cortices as well as the caudate nucleus). However, although this effect was readily reversed in both the piriform cortex and caudate nucleus by pretreatment with apomorphine, this treatment had no effect on the increased dopamine levels observed in the prefrontal and cingulate cortices. In addition, the decline in dopamine levels after synthesis inhibition with alpha-methyltyrosine was significantly faster in the prefrontal and cingulate cortices relative to the caudate nucleus. The piriform cortex showed an intermediate decline which was not significantly different from that observed in any of the other regions.(ABSTRACT TRUNCATED AT 400 WORDS)

A10 dopamine neurons: role of autoreceptors in determining firing rate and sensitivity to dopamine agonists

The present experiments investigated the relationship between the spontaneous basal firing rate of A10 dopamine (DA) neurons and their sensitivity to the rate-suppressant effects of intravenously administered apomorphine (APO) and d-amphetamine (AMP) as well as microiontophoretically ejected DA. The results indicated highly significant inverse relationships between basal neuronal activity and sensitivity to DA and DA agonists, i.e. the faster the spontaneous rate of an A10 DA neuron, the less sensitive that cell was to agonist-induced suppression. This relationship was not found for the rate suppressant effects of iontophoretic gamma-aminobutyric acid. There were no significant differences between the effects of iontophoretic DA on pre-glutamate and glutamate-driven activity of the same A10 DA neurons indicating that faster firing rates, per se, did not determine the sensitivity of these cells to DA agonists. Rather, these results suggest that both spontaneous activity and sensitivity to DA agonists may be determined by the density (or sensitivity) of DA autoreceptors on A10 DA neurons. This hypothesis was supported by the finding that antidromically identified mesocortical DA neurons, which were significantly less responsive to DA, APO and AMP exhibited significantly faster firing rates than other A10 DA neurons. Thus, this subpopulation of A10 DA neurons is primarily made up of cells with low autoreceptor density (or sensitivity).

Role of endogenous substance P in stress-induced activation of mesocortical dopamine neurones

The dopamine (DA) innervation to the forebrain arises from subpopulations of midbrain DA neurones broadly classified as nigrostriatal, mesolimbic and mesocortical. Significant differences in the autoregulatory mechanisms and neuronal inputs of these DA pathways may account for their differences in physiological and pharmacological responsiveness. For example, footshock stress can activate rat mesocortical DA cells but does not alter nigrostriatal DA turnover, while also decreasing substance P (SP) concentrations in the midbrain interpeduncular nucleus and in the adjacent ventral tegmental area (VTA), but not in the substantia nigra (SN). This suggested that the activation of the SP input to the VTA may mediate activation of certain DA systems by footshock stress; behavioural studies also had suggested an excitatory effect of SP on DA cells in the VTA. SP antagonists now available are neurotoxic and of questionable efficacy, we therefore used monoclonal antibody against SP. Antibody microinjected into the VTA prevented normal footshock-induced activation of mesocortical DA neurones, suggesting mediation by SP input to the VTA. The in vivo application of antibodies may prove valuable in studies of neuropeptides in the central nervous system (CNS).