Electrophysiological evidence for non-dopaminergic mesocortical and mesolimbic neurons in the rat

Inhibitory influence of the mesocortical dopaminergic system on spontaneous activity or excitatory response induced from the thalamic mediodorsal nucleus in the rat medial prefrontal cortex

Since the medial prefrontal cortex receives converging projections from the mediodorsal nucleus of the thalamus (MD) and the dopaminergic neurons located in the ventromedial mesenscephalic tegmentum (VMT) the responses of cortical neurons to ipsilateral VMT and MD stimulation (50-150 microA; 0.2-0.5 ms duration) were analyzed in ketamine anaesthetized rats. MD stimulation at 1 Hz blocked the firing of 99% of the spontaneously active cortical units tested (mean latency, 15 ms; mean duration, 182 ms). MD stimulation at 5-10 Hz evoked single spike responses (mean latency, 16 ms) in 80% of the units tested. Ten to 15 days after kainic acid injection into the MD the number of cortical neurons inhibited (1 Hz) or excitated (5-10 Hz was reduced to 57 and 18%, respectively. Following stimulation of the VMT (at a frequency of 1-5 Hz), 85% of cortical neurons showed an arrest of spontaneous firing occurring after a mean latency of 17 ms and lasting 109 ms on the average. Most of the cells displaying the VMT inhibitory effect were excitated by MD stimulation. Moreover VMT stimulation, applied 3-45 ms before that of MD, blocked the excitation induced by MD in 75% of the units tested. After injection of 6-hydroxydopamine into the medial forebrain bundle or intraperitoneal administration of alpha-methyl-paratyrosine (alpha-MpT), the number of units tested responding to VMT stimulation was of 19 and 35%, respectively. Moreover in these treated rats, the proportion of excitatory responses to MD blocked by VMT stimulation was reduced to 5 and 6%.(ABSTRACT TRUNCATED AT 250 WORDS)

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).

Substantia nigra and ventral tegmental area projections to cortex: topography and collateralization

The substantia nigra and ventral tegmental area of the rat were examined by retrograde transport methods to determine the topography and collateralization patterns of projections to cortex and certain subcortical sites. The topographical relationships between cells and their terminal fields were confirmed and clarified by the horseradish peroxidase retrograde transport technique. The collateralization of axons was analyzed by the use of multiple fluorescent tracers. These experiments indicated that individual ventral tegmental area cells do not collateralize extensively to either subcortical or cortical terminal fields. Substantia nigra cells, however, give rise to more highly collateralized axons and single cells may simultaneously innervate different regions of cortex as well as subcortical sites. Substantia nigra cells can be divided with respect to their cortical collateralization patterns into three groups: (1) those that innervate cingulate cortices, (2) those that project to prefrontal and suprarhinal cortices, and (3) those that innervate entorhinal cortex.

Brain reward circuitry: four circuit elements "wired" in apparent series

Activation of a variety of anatomically distinct sites in the central nervous system can produce rewarding states. Four central reward phenomena are amphetamine injections into nucleus accumbens, morphine injections into the ventral tegmental area, electrical stimulation of the ventral tegmental area, and electrical stimulation of the lateral hypothalamic medial forebrain bundle. Current evidence suggests that these four rewarding events trigger activity in elements of a common reward circuit and that the elements are connected in series. The four partially identified elements in this circuit are (1) descending, fast-recovering, short refractory period fibers of the medial forebrain bundle, (2) separate, opioid peptide-containing afferents to the ventral tegmental area, (3) the dopaminergic cells projecting from the ventral tegmental area to nucleus accumbens, and (4) the dopaminoceptive cells of nucleus accumbens.

Intracellular and extracellular electrophysiology of nigral dopaminergic neurons--1. Identification and characterization

Intracellular recordings were obtained from directly identified rat nigral dopamine cells in vivo. This identification was based on an increase in glyoxylic acid-induced catecholamine fluorescence in the impaled dopamine neurons. One of three compounds was injected intracellularly into each cell to produce the heightened fluorescence: (1) L-DOPA, to increase the intracellular dopamine content by precursor loading; (2) tetrahydrobiopterin, a cofactor for tyrosine hydroxylase, to increase intracellular dopamine concentration through activation of the rate-limiting enzyme for dopamine synthesis and (3) colchicine, to arrest intraneuronal transport and thus allow the build-up of dopamine synthesizing enzymes and dopamine in the soma. In addition, dopamine cells were antidromically activated from the caudate nucleus and collision with a directly elicited action potential was demonstrated. Identified dopamine neurons were shown to possess an input resistance of 31.2 +/- 7.4 M omega (means +/- SD) and a time constant of 12.1 +/- 3.2 ms. The action potentials were of long duration (2.75 +/- 0.5 ms) with a marked break between the initial segment and the somatodendritic spike components. The initial segment was the only component commonly elicited during antidromic activation. Spontaneously occurring action potentials were usually preceded by a slow, pacemaker-like depolarization. Burst firing by summation of depolarizing afterpotentials was observed to occur spontaneously, but could not be triggered by short depolarizing current pulses. Intravenously administered apomorphine demonstrated the same inhibitory effect on cell firing that was previously reported to occur when recording extracellularly from identified dopaminergic neurons. The determination of the electrophysiological characteristics of a population of cells directly identified as containing a specific neurotransmitter (in this case, dopamine) may allow one to construct better models of a system's functioning. Thus, the high input resistance and long time constant of dopamine-containing cells, combined with their burst/pause firing mode, may be important functionally with respect to a possible modulatory effect of dopamine in postsynaptic target areas.

Activity of mesencephalic dopamine and non-dopamine neurons across stages of sleep and walking in the rat

Single unit activity of dopamine and non-dopamine neurons in the substantia nigra and ventral tegmental area was recorded across stages of sleep and waking in the rat. These stages consisted of slow wave sleep (SWS), rapid eye movement (REM) sleep, awake-quiet (AQ) and awake-moving (AM). The dopamine neurons showed no change in mean firing rate across the stages of sleep or waking. During REM sleep, however, the dopamine cells fired with a more variable interspike interval than during SWS. In contrast, non-dopamine neurons in the substantia nigra and ventral tegmental area showed large increases in firing rate in REM compared to SWS, and in AM compared to AQ, without showing changes in interspike interval variability. In conclusion, whereas other monoaminergic neurons and various cortical and subcortical neurons exhibit marked changes in firing rate across the stages of sleep and waking, the dopamine neurons are unique in their lack of change in firing rate across stages.

The cytology of dopaminergic and nondopaminergic neurons in the substantia nigra and ventral tegmental area of the rat: a light- and electron-microscopic study

The results of this study support the conclusion that dopaminergic cells can be distinguished from non-dopaminergic cells, at both the light- and electron-microscopic level, by cytological features, and particularly by the pattern of Nissl substance. In both the substantia nigra and the ventral tegmental area, two main categories of cell type can be identified in Nissl preparations: (1) dark-staining, basophilic cells with large masses of Nissl substance and (2) light-staining cells with more translucent cytoplasm. The following findings provide evidence that the basophilic cells of both substantia nigra and ventral tegmental area are the dopaminergic cells. (1) There is a good correlation between the topographic distribution of basophilic cells and that of dopaminergic cells mapped by both histofluorescence and immunohistochemical methods. (2) After unilateral destruction of the dopaminergic neurons by intracerebral injection of 6-hydroxydopamine in the dopaminergic pathway, the basophilic cells in the substantia nigra and ventral tegmental area disappeared on the lesion side, while the lighter-staining cells appeared unaffected. (3) In normal rats, and in rats with unilateral 6-hydroxydopamine lesions, intraventricular injection of [3H]norepinephrine was used for specific labeling of dopaminergic neurons. In autoradiograms of semithin sections, such labeling was observed only in dark-staining and not in light-staining cells, and in cases of unilateral 6-hydroxydopamine lesion was totally absent on the lesion side. Electron-microscopy showed much of the cytoplasm of the basophilic dopaminergic cells to be densely filled with free ribosomes associated with large, well organized complexes of rough endoplasmic reticulum. The cytoplasm of the light, non-dopaminergic cells contains only sparse free ribosomes and small, widely spaced aggregates of rough endoplasmic reticulum. Both cell types occur in a similar variety of size and shape.

Ventral mesencephalic tegmentum (VMT) controls electrocortical beta rhythms and associated attentive behaviour in the cat

When a cat is immobile, very alert and displaying behaviour suggesting focused attention toward a target in its environment, beta rhythms (ca. 40 Hz) develop in the fronto-parietal cortical areas. After bilateral electrolytic lesions of the ventral mesencephalic tegmentum (VMT), these beta rhythms are suppressed (while other cortical activities, with other behavioural correlates, persist), and at the same time, attentive immobility is no longer observed: the same experimental situation as in the control now elicits locomotor hyperactivity. Arguments are produced, favouring the hypothesis that both behavioural immobility and the accompanying thalamocortical beta rhythms are controlled through one of the dopaminergic system that originate from the VMT and are distinct from the nigrostriatal one.

The projections of the ventral tegmental area and adjacent regions: a combined fluorescent retrograde tracer and immunofluorescence study in the rat

The organization of projection neurons in the ventral tegmental area (VTA), and in adjacent parts of the raphe nuclei medial to it (the central and rostral linear, and interfascicular nuclei), the mammillary body (the supramammillary region and the tuberomammillary nucleus), and the substantia nigra have been examined in the rat with Kuypers' retrograde double labeling method, and with a combined retrograde labeling (with true blue)-immunohistochemical method for the demonstration of dopaminergic neurons. First, the distribution, within the VTA and adjacent regions, of dopaminergic and non-dopaminergic cells that project to terminal fields in the telencephalon (nucleus accumbens, lateral septum, pre- and supragenual fields of the anterior limbic cortex, amygdala, dorsal hippocampus, and entorhinal area), in the diencephalon (lateral habenula), and in the brainstem (locus coeruleus, and parabrachial nucleus) was determined. Then, 15 different combinations of injections of the tracers bisbenzimide and true blue into different terminal fields were made to determine whether individual cells in the region of the VTA send collaterals to more than one site. Taken together, the results indicate that essentially separate groups of cells in the VTA and adjacent regions of the raphe project to each terminal field. In addition, each group can be further divided into dopaminergic and non-dopaminergic components, although the proportion of dopaminergic cells in each group can vary from over 80% (e.g., to the nucleus accumbens) to less than 1% (to the lateral habenula and to the locus coeruleus). In addition, it was found that the supramammillary region, which contains a dense extension of the A10 cell group in its medial part, and the tuberomammillary nucleus, project to, or through, most of the regions injected with retrograde tracers. Virtually all of the projections from the VTA and adjacent regions are partially crossed, the percentage of cells on the uninjected side ranging from over 40% (e.g., for locus coeruleus injections) to only about 2% (e.g., for amygdalar injections). Most of the groups of projection neurons in the region of the VTA are considerably intermixed with the exception of those that project to the lateral septum, to the lateral habenula, and to the hippocampal formation, which are concentrated in ventral and medial parts of the VTA, and in the raphe nuclei medial to the VTA. It was concluded that in the ventral part of the midbrain, essentially separate groups of aminergic and non-aminergic neurons in both the reticular formation (VTA) and in the adjacent nuclei of the raphe project bilaterally to a variety of similar terminal fields in the telencephalon, diencephalon, and brainstem. Further work at the single cell level is needed to determine whether these cell groups are differentially innervated by known inputs to the VTA and adjacent regions, most of which appear to descend through the medial forebrain bundle from sites in the limbic system and hypothalamus.

Response of nucleus accumbens neurons to amygdala stimulation and its modification by dopamine

Extracellular single unit recordings were obtained from the nucleus accumbens of urethane anesthetized rats. It was found that electrical stimulation of the basal lateral and basal medial nuclei of the amygdala produced strong excitatory responses in neurons of the nucleus accumbens, in particular the medial region. Latencies of activation were relatively short with a mean of 10.7 ms. Dopamine applied iontophoretically had a marked attenuating effect on the excitatory response of nucleus accumbens neurons to amygdala stimulation. The spontaneous activity of all neurons recorded from the nucleus accumbens was also suppressed by dopamine, but the excitatory response was more sensitive to dopamine inhibition than the spontaneous activity. Neurons in the nucleus accumbens showed a variety of responses to single-pulse electrical stimulation of the ventral tegmental area (VTA). Some units in the nucleus accumbens received convergent inputs from both the amygdala and the VTA. Stimulation of the VTA also attenuated the response of nucleus accumbens neurons to excitatory inputs from the amygdala. A train of 10 pulses (0.15 ms, 200--600 microA) at 10 Hz delivered to the VTA at 100 ms before stimulation of the amygdala caused attenuation of the original excitatory response. The attenuating effect could be observed irrespective of whether individual single-pulse stimulation of the VTA elicited a response in that particular accumbens neuron or not. 6-Hydroxydopamine injected into the VTA 2 days prior to the recording experiment, or haloperidol injected intraperitoneally 1 h before the recording session, abolished this attenuating effect. However, responses to single-pulse stimulations of the VTA were not abolished. The results suggest that the attenuation of the excitatory response to amygdala stimulation was due to the release of dopamine from mesolimbic dopaminergic neurons. Responses to single-pulse stimulations of the VTA were probably due to activation of non-dopaminergic neurons projecting from the same area. It is suggested as a working hypothesis that this inhibitory effect of dopamine may be an important function of the mesolimbic dopamine pathway in modulating the extent to which limbic structures can exert an influence on the motor system through the accumbens.

The organization of dopaminergic and non-dopaminergic mesencephalo-cortical neurons in the rat

The dopamine containing mesencephalo-cortical pathway was studied in the rat by means of a combined retrograde fluorescent tracing and catecholamine histofluorescence technique. After large injections of the fluorescent retrograde tracer, Evans blue, into the frontal cortex, many neural somata of the ventral midbrain tegmentum were retrogradely labeled; most of the retrogradely labeled neurons also showed catecholamine fluorescence. However, some labeled cells (10-15%) did not show any catecholamine fluorescence. The present findings confirm the existence of a non-dopaminergic (DA) mesencephalo-cortical pathway and describe the topographical interrelationships between its DA and the non-DA cell bodies of origin.

Reduction of dopamine utilization in the prefrontal cortex but not in the nucleus accumbens after selective destruction of noradrenergic fibers innervating the ventral tegmental area in the rat

The present study was made to determine the role of the noradrenergic (NA) neurons which innervate the ventral tegmental area (VTA) in the regulation of VTA dopaminergic (DA) neurons projecting to the prefrontal cortex and the nucleus accumbens. For this purpose, a 6-hydroxydopamine lesion was made in benztropine pretreated rats medially just above the decussatio of the pedunculus cerebellaris superior in order to specifically destroy the NA fibers innervating the VTA without affecting those projecting to the prefrontal cortex. Seven days later the ratio of DOPAC and DA levels was estimated in the prefrontal cortex and the nucleus accumbens and used as an index of DA utilization. In the lesioned rats the DOPAC/DA ratio was significantly decreased in the prefrontal cortex but not in the nucleus accumbens. These results suggest that the NA neurons which innervate the VTA exert a specific tonic excitatory influence on the mesocortico-prefrontal DA neurons.

GABAergic mechanisms within the ventral tegmental area: involvement of dopaminergic (A 10) and non-dopaminergic neurones

The spontaneous activity of rats was measured after activation or inhibition of GABA activity in the ventral tegmental area of the midbrain (VTA). Six hours after bilateral injection of ethanolamine-o-sulphate (GABA agonist) into the VTA, the behavioural activation induced either by d-amphetamine (amph) or by bilateral VTA infusion of a long-lasting enkephalin analogue was completely blocked. Bilateral infusion of picrotoxin (GABA antagonist) into the VTA elicited a short-lived (40 min) dose-dependent behavioural activation which was not reduced either by prior specific lesion of the meso-cortico-limbic dopaminergic neurones or by administration of the opiate antagonist naloxone. Moreover, the simultaneous administration of picrotoxin and amph induced complex changes in behaviour which consisted of additive effects during the first 40 min, followed by an inhibition of the activating effect of amph. Our findings indicate that GABA-mediated inhibition involves both dopaminergic and non-dopaminergic neurones within the VTA, and possible implications for human pathology are discussed.

Effects of peripheral stimulation on the activity of neurons in the ventral tegmental area, substantia nigra and midbrain reticular formation of rats

Extracellular recordings were obtained from neurons in the ventral tegmental area (VTA), the substantia nigra, including the zona compacta (SNC) and the zona reticulata (SNR), and the midbrain reticular formation (FOR) of adult female albino rats anesthetized with urethane and chloral hydrate. Based on electrophysiological characteristics the neurons were divided into two types. Type I neurons, with relatively long spike durations and slow discharge rates, were confined to the VTA and SNC. Type II neurons, with shorter spike durations and faster discharge rates, were observed in the SNR and FOR as well as the VTA and SNC. The effects of foot pinch (FP), tail pinch (TP) and stimulation of the vaginal cervix (VC) on the activity of the two types of neurons were investigated. Previously it was demonstrated that FP was aversive, TP elicited locomotion, sniffing and gnawing responses and VC lordosis response, vocalization and immobility. For approximately two-thirds of the neurons the effects of the three peripheral stimuli were similar; either they were activated or suppressed. Approximately 8 percent of the neurons were suppressed by FP and TP and activated by VC whereas a similar number were activated by FP and TP and suppressed by VC. Type 1 and Type II neurons in the VTA and SN were activated and suppressed by the peripheral stimuli with suppression being the most common response to FP and TP. The results are consistent with the view that VTA and SN neurons integrate a number of central and peripheral inputs.

Inhibition from ventral tegmental area of nucleus accumbens neurons in the rat

The role of the ventral tegmental area (VTA), which is rich in dopamine-containing cell bodies, on nucleus accumbens (Acc) neurons was examined. In Acc neurons receiving input from parafascicular nucleus (Pf) of thalamus, VTA conditioning stimulation produced an inhibition of spike generation with Pf stimulation. In contrast, VTA conditioning stimulation did not affect Acc neurons receiving input from limbic structures such as the amygdala nucleus and hippocampus.

A comparison of the effects of electrical stimulation of the lateral and ventromedial hypothalamus on the activity of neurons in the ventral tegmental area and substantia nigra

Extracellular unit recordings were obtained from neurons in the ventral tegmental area (VTA), the substantia nigra, zona compacta (SNC) and zone reticulata (SNR) of adult female albino rats anaesthetized with urethane and chloral hydrate. Neurons were divided into two types based on their electrophysiological characteristics; Type I neurons had long duration action potentials (greater than 2.6 msec) and slow discharge rates and Type II neurons had shorter duration action potentials and a wider range of discharge rates. Both types of neurons were found in the VTA and SNC, but there were only Type II neurons in the SNR. The effects of single pulse stimuli delivered to the ipsilateral ventromedial (VMH) or lateral (LH) hypothalamic areas on activities of the two types of neurons were investigated. Only a small portion of neurons in the VTA and SNC responded to VMH stimulation, but in contrast a majority of the two types of neurons in the VTA and SNC responded to LH stimulation. Most neurons in the SNR did not respond to VMH and LH stimulation. Type iI neurons in the VTA and SNC were predominantly suppressed by LH stimulation with short onset latencies (less than 6 msec), indicating the possibility of monosynaptic mediation. However Type I neurons in the VTA and SNC were activated and suppressed and the onset latencies of these responses were relatively longer. The high proportion of neurons of VTA and SNC responding to electrical stimulation of LH is consistent with anatomical evidence. Suppression and activation of Type I neurons in VTA and SNC suggest that the LH exerts modulatory influences on these neurons of the midbrain.

Opposite changes in dopamine utilization in the nucleus accumbens and the frontal cortex after electrolytic lesion of the median raphe in the rat

As revealed by the changes in dihydroxyphenylacetic acid (DOPAC) levels and in the DOPAC/Dopamine (DA) ratio, DA utilization was markedly enhanced in the nucleus accumbens and reduced in the prefrontal cortex of rats five days after the electrolytic lesions of the median raphe. These opposite effects were not seen any more seventeen days after the injection. These results suggest that neurones originating from the median raphe and projecting to the ventral tegmental area exert an opposite effect on the activity of DA cells innervating the nucleus accumbens and on those projecting to the prefrontal cortex.