Increased midbrain dopaminergic cell activity following 2'CH3-MPTP-induced dopaminergic cell loss: an in vitro electrophysiological study

Several days after the administration of 1-methyl-4-(2'-methylphenyl)-1,2,3,6-tetrahydropyridine (2'CH3-MPTP) to the BALB/cJ mouse there is a loss of midbrain dopaminergic neurons, a reduction of forebrain dopamine (DA) content, and an elevation in forebrain DA turnover. The purpose of the present study was to determine whether the increase in forebrain DA turnover is related to an increase in dopaminergic neuronal activity. In vitro extracellular single unit recordings were made from midbrain dopaminergic neurons in the substantia nigra pars compacta (nucleus A9) and ventral tegmental area (nucleus A10) of BALB/cJ mice. The experimental animals were treated intraperitoneally with 40, 50 or 55 mg/kg 2'CH3-MPTP and killed 7-15 days later. Forebrain DA concentrations were decreased below control values by the two higher toxin doses in the caudate-putamen (67% and 78%, respectively), but not in the nucleus accumbens. DA turnover increased more than 2-fold in the caudate-putamen, but was unchanged in the nucleus accumbens. Nucleus A9 cells, in the 2'CH3-MPTP-treated animals, exhibited a 3-fold increase in the number of spontaneously active cells, and an 84% increase in basal firing rates. There was also a positive correlation between the A9 cell firing rates, and the DA turnover in the striatum of the toxin-treated mice. Nucleus A10 cells, in the 2'CH3-MPTP-treated animals, exhibited neither changes in number of spontaneously active cells nor changes in firing rates.(ABSTRACT TRUNCATED AT 250 WORDS)     

1-Methyl-4-(2'-methylphenyl)-1,2,3,6-tetrahydropyridine (2'CH3-MPTP)-induced degeneration of mesostriatal dopaminergic neurons in the mouse: biochemical and neuroanatomical studies

The neurotoxic effects of 1-methyl-4-(2'-methylphenyl)-1,2,3,6-tetrahydropyridine (2'CH3-MPTP), a substituted analog of 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine, were studied in BALB/cJ mice. Moderate doses of 2'CH3-MPTP produced a greater depletion of dopamine (DA) in the striatum (45%) than in the nucleus accumbens (23%), and in these same animals, there was a 35% loss of midbrain DA neurons. The greatest loss of DA cells occurred within the substantia nigra (43%), and there was also a significant loss of cells within the ventral tegmental area (28%). Higher doses of 2'CH3-MPTP decreased levels of DA more in the axon terminal/forebrain region (72%) than in the cell body/midbrain region (25%). Similar forebrain/midbrain DA depletion ratios were also found in mice that received an electrolytic lesion of the midbrain DA neurons; there was a greater Da depletion in the forebrain (29%) than in the midbrain (8%). In both 2'CH3-MPTP and electrolytically lesioned animals there was a significant increase in DA turnover in the forebrain region, as measured by the homovanillic acid/DA ratio. These data indicate that 2'CH3-MPTP: (1) destroys DA neurons within two midbrain regions containing cells which project to the striatum (i.e. mesostriatal DA neurons), rather than just nigrostriatal DA neurons; (2) produces a greater loss of DA in the axon terminal region than in the cell body region; and (3) influences the mesostriatal DA neurons in the same way as does a lesion to the cell bodies. These data are discussed with regard to the pathophysiology of 2'CH3-MPTP.     

Altered dopaminergic function in the prefrontal cortex, nucleus accumbens and caudate-putamen of an animal model of attention-deficit hyperactivity disorder — the spontaneously hypertensive rat

The spontaneously hypertensive rat (SHR) has been proposed as an animal model for Attention-Deficit Hyperactivity Disorder (ADHD). The behavioural problems of ADHD have been suggested to be secondary to altered reinforcement mechanisms resulting from dysfunction of the mesolimbic and mesocortical dopaminergic systems. The present study therefore investigated whether there are regional differences in dopamine (DA) and acetylcholine (ACh) release and DA D₂-receptor function in SHR compared to their normotensive Wistar-Kyoto (WKY) controls. The DA D₂-receptor agonist, quinpirole, caused significantly greater inhibition of DA release from caudate-putamen but not from nucleus accumbens or prefrontal cortex slices of SHR relative to WKY. DA D₂-receptor blockade by the antagonist, sulpiride, caused a significantly greater increase in DA release from nucleus accumbens slices of SHR compared to WKY suggesting increased efficacy of DA autoreceptors at low endogenous agonist concentrations in the nucleus accumbens of SHR. The electrically-stimulated release of DA was significantly lower in caudate-putamen and prefrontal cortex slices of SHR than in slices of WKY. This could be attributed to increased autoreceptor-mediated inhibition of DA release in caudate-putamen slices but not in the prefrontal cortex. No difference was observed between SHR and WKY with respect to DA D₂-receptor-mediated inhibition of ACh release from caudate-putamen or nucleus accumbens slices, suggesting that postsynaptic DA D₂-receptor function is not altered in SHR relative to WKY.     

Biochemical and electrophysiological evidence that RO 60-0175 inhibits mesolimbic dopaminergic function through serotonin2C receptors

In vivo microdialysis and electrophysiological techniques were used to elucidate the role of the 5-HT₂ receptor family on the control of mesolimbic dopaminergic system exerted by serotonin (5-HT). Administration of RO 60-0175 (1 mg/kg, i.p.), a selective 5-HT_2C receptor agonist, significantly decreased dopamine (DA) release by 26±4% (below baseline) 60 min after injection. Moreover, RO 60-0175 (80–320 μg/kg, i.v.) dose-dependently decreased the basal firing rate of DA neurons in the ventral tegmental area (VTA), reaching its maximal inhibitory effect (53.9±15%, below baseline) after the dose of 320 μg/kg. The selective 5-HT_2C receptor antagonist SB 242084 completely blocked the inhibitory action of RO 60-0175 on accumbal DA release and on the firing rate of VTA DA cells. On the contrary, both (±)-DOI, a mixed 5-HT_2A/2C receptor agonist, and the selective 5-HT_2B agonist BW 723C86, did not affect either DA release in the nucleus accumbens or the firing rate of VTA DA cells. Taken together, these data confirm that central 5-HT system exerts an inhibitory control on the mesolimbic DA system and that 5-HT_2C receptors are involved in this effect.     

Nucleus A10 dopaminergic neurons in inbred mouse strains: Firing rate and autoreceptor sensitivity are independent of the number of cells in the nucleus

Inbred mouse strains have different numbers of midbrain dopaminergic neurons; for example, BALB/cJ mice have 20–25% more neurons than CBA/J mice. As the number of cells decrease, for example in Parkinson's disease and in animals with midbrain dopaminergic cell lesions, the activity of their remaining cells increases. The purpose of the present experiment was to determine whether the functional properties of dopaminergic neurons in the ventral tegmental area (nucleus A10) differ in inbred mouse strains which possess different numbers of cells. The firing rate and autoreceptor sensitivity of A10 dopaminergic cells were examined in the in vitro slice preparation in BALB/cJ, C3H/HeJ, CBA/J, and DBA/2J mouse strains. It was observed that the autoreceptors on mouse dopaminergic neurons exhibit pharmacological properties of dopamine autoreceptors; activation of the autoreceptor produced a marked inhibition (50–70%) in cell firing rate by quinpirole (10⁻⁸ M), LY-141865 (10⁻⁷ M), (+)-3-(3-hydroxyphenyl)-N-n-propyl-piperidine (10⁻⁶ M), propyl-norapomorphine (10⁻⁵ M) and dopamine (10⁻⁴ M), and this inhibition was blocked or reversed by specific dopamine D2 receptor antagonists [(−) sulphide and spiroperidol, 10⁻⁶ M]. The baseline firing rates of the A10 cells did not differ among the four inbred strains [range 2.5 ± 0.2 (C3H/HeJ)−3.4 ± 0.3 (CBA/J) spikes/s ±SEM], and there was no significant difference in autoreceptor sensitivity among the mouse strains as assessed either by superfused dopamine (inhibitory dose 50% ≈150 μM), or by superfused quinpirole (inhibitory dose 50% ≈10 nM). These data indicate that differences in A10 cell numbers of 30% do not significantly influence the baseline firing rate or autoreceptor sensitivity of the cells.     

Genetic variations in midbrain dopamine cell number: Parallel with differences in responses to dopaminergic agonists and in naturalistic behaviors mediated by central dopaminergic systems

Mice of the inbred strain BALB/cJ have more midbrain dopaminergic cell bodies and greater activity of the catecholamine-synthesizing enzyme, tyrosine hydroxylase (TH), in the nigrostriatal and mesolimbic dopaminergic systems than mice of the CBA/J strain. This difference in cell number and TH activity in the midbrain dopaminergic systems are paralleled by differences in drug responses and behaviors which are dependent on the release of dopamine in midbrain dopaminergic system. BALB/cJ mice showed greater locomotion and stereotypy than CBA/J mice after D-amphetamine (2-20 mg/kg, i.p.). There was no difference in the amount of amphetamine accumulated in brain at the peak of drug response or in the duration of drug effect, suggesting that the differences in behavioral effect were not due to strain differences in pharmacokinetic distribution of the drug. In contrast to the greater stereotypy to D-amphetamine, BALB/cJ mice showed less stereotypy after apomorphine (2-10 mg/kg, i.p.) than CBA/J mice. BALB/cJ mice also showed more exploration than CBA/J mice, measured as locomotion and rearing in a novel open field and investigation of a novel object. Genetically determined differences in the number of midbrain dopaminergic cell bodies and in the relative density of innervation of DA terminals in target fields and in TH activity in the nigrostriatal and mesolimbic dopaminergic systems are paralleled by difference in behavioral responses mediated by release of dopamine. The number of cells of a particular neurochemical class may dictate the magnitude of behaviors, drug-induced or spontaneous, mediated by those neurons.     

Electrophysiological effects of cholecystokinin octapeptide on identified rat nigrostriatal dopaminergic neurons

Cholecystokinin octapeptide (CCK-8) exists in a subpopulation of midbrain dopaminergic (DA) neurons and has been shown to affect the activity of unidentified DA cells. This study describes the effects of the sulfated (CCK-8S) and unsulfated (CCK-8US) peptides (8 micrograms/kg, i.v.) on the ability of apomorphine to inhibit the firing rate of nigrostriatal DA cells identified by antidromic activation from the caudate nucleus of anesthetized rats. CCK-8S excited 9/25 DA cells while CCK-8US was without effect on firing rate (n = 9). CCK-8S pretreatment resulted in complex changes in the sensitivity of nigrostriatal DA cells to apomorphine which were related to whether an initial excitatory response was elicited by CCK-8S. CCK-8US did not alter apomorphine sensitivity. These results suggest that CCK-8S can exert modulatory effects on DA cells independent of a direct excitatory action. The effect of acute CCK-8 injection on the number of spontaneously active DA cells in stereotaxically defined regions of the substantia nigra and ventral tegmental area was also determined. CCK-8S doubled the number of active cells in these areas; CCK-8US did not alter the population activities.     

Persistence of the releasable pool of CCK in the rat nucleus accumbens and caudate-putamen following lesions of the midbrain

Previous studies have identified populations of dopamine neurons in the midbrain that colocalize cholecystokinin some of which project to the nucleus accumbens and caudate-putamen. The contribution of dopamine-colocalized peptide to the total releasable pool of cholecystokinin in these brain regions was investigated using microdialysis. Dopamine, dihydroxyphenylacetic acid and cholecystokinin immunoreactive levels in dialysates of the posterior medial nucleus accumbens and medial caudate-putamen were determined following 6-hydroxydopamine lesions of the ventral tegmental area and substantia nigra or transection of the medial forebrain bundle. An 89–99% depletion in basal extracellular dihydroxyphenylacetic acid and an 87–99% decrease in veratridine-evoked extracellular dopamine levels was observed in the nucleus accumbens and caudate-putamen, 4 weeks after 6-hydroxydopamine lesion. No statistically significant difference was observed between lesioned and control animals in the basal or veratridine-evoked extracellular level of cholecystokinin immunoreactivity in either region. Similarly, transection of the medial forebrain bundle failed to significantly deplete the releasable pool of cholecystokinin immunoreactivity in the nucleus accumbens or caudate nucleus despite 89–99% depletions of dopamine and its metabolite. These data suggest that midbrain dopamine or non-dopaminergic cells are not the primary source of releasable cholecystokinin in the posterior medial nucleus accumbens and medial caudate-putamen measured by microdialysis.     

Mesostriatal and mesolimbic projections of midbrain neurons immunoreactive for estrogen receptor beta or androgen receptors in rats

The dopamine (DA) inputs to the caudate putamen, the nucleus accumbens, and the amygdala in rats are sensitive to circulating estrogens and androgens. One mechanism for the hormone modulation of these systems may be via actions at cognate intracellular estrogen and androgen receptors. However, although it is known that specific subsets of midbrain DA neurons are immunopositive for estrogen receptor beta (ERbeta) or androgen receptors (ARs), it is not known where these receptor-bearing cells project. To address this issue, we combined double-label immunocytochemistry with retrograde tract tracing to identify the forebrain projections of ERbeta- or AR-immunoreactive (IR) midbrain neurons. Specifically, Fluoro-Gold and/or cholera toxin were injected into discrete subregions of the caudate-putamen, the nucleus accumbens, or the amygdala. Evaluations of the resultant midbrain labeling revealed that ERbeta-IR neurons sent collateral projections mainly to both the ventral caudate-putamen and the amygdala, but not to the dorsal caudate or nucleus accumbens. In contrast, AR-IR neurons projected either to the amygdala or the nucleus accumbens but not to the caudate-putamen. The organization of these forebrain projections concurs with some of the known hormone sensitivities of mesostriatal and mesolimbic DA systems in rats and provides an anatomical model that predicts separate influences for androgens and estrogens over mesostriatal and mesolimbic DA systems.     

Effects of electrical stimulation of the central nucleus of the amygdala on the in vivo electrophysiological activity of rat nigral dopaminergic neurons

The central nucleus of the amygdala (CeA) receives a dopaminergic (DA) innervation from the midbrain. Among its many efferent projections, the CeA innervates the substantia nigra. The possibility that the CeA influences the activity of nigral DA neurons was evaluated. The effects of electrical stimulation of the CeA on the firing rate and pattern of nigral DA neurons were investigated in anesthetized rats. Poststimulus time histograms revealed that nigral DA cells were either inhibited (N = 15), excited (N = 13), or unresponsive (N = 17) to CeA stimulation (250 stimuli a t 0.5 H_z). The mean (±SEM) latency to inhibition (24 ± 9 msec) was significantly shorter than that for excitation (65 ± 10 msec); the duration of inhibition (200 ± 29 msec) was also significantly greater than the duration of excitation (86 ± 11 msec) (P < 0.01 for both). DA cells that were excited had basal firing rates significantly lower than those of the inhibited or unresponsive cells (P < 0.05). Preliminary data suggest that DA cell burst-firing increases or decreases, respectively, in association with stimulation-evoked increases or decreases in firing rate. The relatively long latencies for stimulation-evoked responses suggest that CeA projection neurons indirectly affect nigral DA neurons via polysynaptic pathways. These results demonstrate that the CeA has the ability to influence the activity of nigral DA neurons, consistent with the putative role of the CeA as an interface between the limbic and extrapyramidal systems. Given the crucial role of the amygdala in anxiety states, these findings suggest that DA cell function may also be affected in such disorders. © 1995 Wiley-Liss, Inc.     

Opioid receptors in midbrain dopaminergic regions of the rat II. Kappa and delta receptor autoradiography

Summary Opiates and opioid peptides are known to influence the dopaminergic (DA) neurons in the midbrain. The purpose of this study was to map and quantify the density of kappa and delta opioid receptor subtypes in the retrorubral field, substantia nigra, and ventral tegmental area and related nuclei, which contain DA nuclei A8, A9, and A10, respectively. Sections through the rostral-caudal extent of the rat midbrain were stained with an antibody against tyrosine hydroxylase, as a DA cell marker, and comparable sections were processed for in vitro receptor autoradiography using the kappa-selective ligand, U-69593, and the delta-selective ligand, D-Pen², D-Pen⁵-enkephalin. In general, both kappa and delta ligands exhibited low levels of specific binding in regions occupied by the midbrain DA neurons.Kappa binding (4–8 fmol/mg tissue) was high throughout the rostral-caudal extent of the substantia nigra, in rostral portions of the ventral tegmental area, and in the nucleus paranigralis; low binding occurred in the retrorubral field and central linear nucleus raphe.Delta binding (6–18 fmol/mg tissue) was high in the caudal portion of the substantia nigra pars reticulata, and in the medial terminal nucleus of the accessory optic system (a region previously shown to contain DA dendrites). The kappa and delta receptor binding is heterogeneously distributed in regions occupied by midbrain dopaminergic neurons, and several fold lower than the binding of mu opioid receptors in the same brain regions.     

Electrophysiological effects of MK-801 on rat nigrostriatal and mesoaccumbal dopaminergic neurons

The electrophysiological effects of the non-competitive (NMDA) antagonist (+)-MK801 (MK-801) on nigrostriatal and mesoaccumbal dopaminergic (DA) neurons were evaluated in chloral hydrate-anesthetized rats. MK-801 (0.05–3.2 mg/kg, i.v.) stimulated the firing rates of 14 (74%) of 19 nigrostriatal DA (NSDA) neurons and all 16 mesoaccumbal DA (MADA) neurons tested. Stimulatory effects of the drug were more prominent on MADA neurons. Interspike interval analysis revealed that MK-801 also regularized DA neuronal firing pattern. Acute brain hemitransection between the midbrain and forebrain attenuated the stimulatory effects of MK-801 on firing rate and blocked the effects on firing pattern. Similar to MK-801, hemitransection itself increased NSDA and MADA cell firing rates and regularized firing pattern. Both i.v. and iontophoretic MK-801 blocked the excitatory effects of iontophoretic NMDA but did not effect excitations caused by the non-NMDA glutamatergic receptor agonists quisqualate and kainate. Iontophoretic MK-801 had no effect alone. These results suggest that the excitatory effects of i.v. MK-801 on DA neuronal activity are not due to direct actions on DA neurons. Glutamatergic projections originating anterior to the hemistransection appear to play a role in the effectrs of MK-801 on DA neuronal activity.     

Repeated administration of Sigma ligands alters the population activity of rat midbrain dopaminergic neurons

Acute and repeated administration of antipsychotic drugs produce distinctive profiles of electrophysiological effects on the population activity of midbrain dopaminergic (DA) neurons which correlate with their clinical effects. Sigma receptors have been hypothesized to be involved in psychosis and in the efficacy of antipsychotic drugs, but little is known about the effects of repeated treatment with sigma ligands on the activity of midbrain DA neuronal populations. In the present study, the cells-pertrack cell-sampling method was used to evaluate the effects of 3 sigma ligands on the numbers of spontaneously active A9 and A10 DA neurons in chloral hydrate-anesthetized rats. One-hour pretreatment with either (+)-pentazocine (10 mg/kg, i.p.), DTG (2 mg/kg, i.p.), or JO 1784 (1 or 10 mg/kg, s.c.) did not alter the number of spontaneously active DA neurons encountered per electrode track. Repeated treatment (21 daily injections) with (+)-pentazocine (1 or 10 mg/kg) or DTG (0.2 or 2 mg/kg) increased the number of A10 DA cells per track; JO 1784 (10 mg/kg but not 1 mg/kg) moderately decreased the number of active A9 DA cells and increased the firing rate of A10 DA neurons. The effect of JO 1784 on A9 DA neurons was not due to depolarization inactivation. The effects of all 3 sigma ligands differ from those of antipsychotic drugs, all of which inactivate A10 DA neurons after repeated treatment. Clinical studies are necessary to determine if selective sigma ligands will provide a novel alternative to DA antagonists in the treatment of psychosis. © 1993 Wiley-Liss, Inc.     

Mapping of locomotor behavioral arousal induced by microinjections of dopamine within nucleus accumbens septi of rat forebrain

Dopamine (DA) at ca. ED₅₀ (16 μg) or saline was stereotaxically microinjected unilaterally 2 h after pretreatment with an MAO inhibitor into left or right nucleus accumbens septi of 697 freely moving rats (1394 injections) to define subregions involved in DA-induced behavioral arousal throughout the anatomical extent of the accumbens. Locomotion was quantified electronically and behavioral responses were assigned to histologically verified injection sites; postural or stereotyped behaviors characteristic of DA injections in caudate-putamen did not occur. Screening with 60 injections across mid-accumbens (2.2–3.2 mm rostral to bregma) indicated that locomotion was elicited non-homogeneously, and was particularly intense dorsomedially. Sites yielding intense arousal and their inactive surround were mapped along the rostrocaudal axis (1.4–4.2 mm anterior to bregma) in coronal sections. Responses to DA showed lateral symmetry and were similar across rostrocaudal levels, with intense responses in dorsomedial accumbens along its border with the caudate-putamen. This functional localization does not coincide closely with reported distributions of DA or its receptors, nor with histologically or histochemically defined core-shell regions of this limbic structure. Nucleus accumbens in rat brain thus appears to be organized functionally into distinct subregions differing markedly in ability to produce locomotor hyperactivity in response to exogenous DA.     

Burst firing in midbrain dopaminergic neurons

Midbrain dopaminergic (DA) neurons fire bursts of activity in response to sensory stimuli, including those associated with primary reward. They are therefore conditional bursters – the bursts conveying, amongst other things, motivationally relevant information to the forebrain. In the forebrain, bursts give rise to a supra-additive release of dopamine, and possibly favour the release of co-localised neuropeptides. Evidence is presented that in rat DA neurons, bursts are engendered by the activity of cortically-regulated afferents. Certain factors are identified which, in combination, lead to burst production: (1) A burst of activity in EAAergic afferents to DA neurons arising from non-cortical sources, but controlled by the medial prefrontal cortex; (2) N-methyl-

Full-size image

-aspartate receptor activation, producing a slow depolarising wave in the recipient neuron; (3) activation of a high threshold, dendritically located calcium conductance which produces a ‘plateau potential'; (4) activation of a calcium-activated potassium conductance, which terminates the burst. These factors are argued to operate in the context of an ‘optimal' level of intracellular calcium buffering for bursting. Other factors which appear to be involved in bursting in other systems, in particular a low threshold calcium conductance, are rejected as being necessary for bursting in DA neurons. The factors which do play a crucial role in burst production in DA neurons are integrated into a theory from which arises a series of hypotheses amenable to empirical investigation. Additional factors are discussed which may modulate bursting. These may either act indirectly through changes in membrane potential (or intracellular calcium concentration), or they may act directly through an interaction with certain conductances, which appear to promote or inhibit burst firing in DA neurons.     

Inhibition of A9 and A10 dopamine cells by the cholecystokinin-B antagonist LY262691: Mediation through feedback pathways from forebrain sites

The diphenylpyrazolidinone cholecystokinin-B (CCK-B) antagonist LY262691 has been shown to decrease the number of spontaneously active dopamine (DA) cells in the ventral tegmental area (Al0) and substantia nigra (A9) of the anesthetized rat. In the present study, we examined the localization of the receptors mediating these effects of LY262691 on A9 and A10 DA cells. In one group of anesthetized rats, the effects of systemic administration of LY 262691 on the number of spontaneously active A9 or A10 DA cells was determined using extracellular, single-unit recordings after radio frequency lesions were placed in the nucleus accumbens, caudate-putamen, or medial prefrontal cortex. Lesions of the caudate-putamen blocked the effects of systemically administered LY262691 on the number of spontaneously active A9, but not A10, DA cells. Conversely, lesions of the n. accumbens blocked the effects of systemically administered LY262691 on A10, but not. A9, DA cells. Lesions of the medial prefrontal cortex blocked the effects of systemically administered LY262691 on both A9 and A10 DA cells. In a separate group of anesthetized rats, the number of spontaneously active A9 or A10 DA cells was determined after LY262691 was microinjected into the n. accumbens, caudate-putamen, or medial prefrontal cortex. Microinjection of LY262691 into the caudate-putamen led to a significant decrease in the number of spontaneously active A9, but not A10, DA cells. Conversely, microinjection of LY262691 into the n. accumbens or medial prefrontal cortex led to a significant decrease in the number of spontaneously active A10, but not A9, DA cells. Microinjection of a structurally related CCK-A antagonist (LY219057) into the n. accumbens or medial prefrontal cortex did not affect the number of spontaneously active A10 DA cells, and microinjection of LY219057 into the caudate-putamen did not affect the number of spontaneously active A9 DA cells. These results indicate that, consistent with known feedback pathways between forebrain structures and midbrain DA neurons, the effects of LY262691 on A9 cells are mediated, at least in part, by antagonism of CCK-B receptors in the caudate-putamen, whereas the effects of LY262691 on A10 cells are mediated, at least in part, by antagonism of CCK-B receptors in the n. accumbens and medial prefrontal cortex. © 1993 Wiley-Liss, Inc.     

Relationship between the locomotor hyperactivity induced by A10 lesions and the destruction of the frontocortical dopaminergic innervation in the rat

Bilateral high frequency lesions of the ventral tegmental area (VTA) in the rat induce a behavioral syndrome characterized by a permanent locomotor hyperactivity and a reduction of attention capacities. The VTA contains the cell bodies of the mesocortical and mesolimbic dopaminergic (DA) systems but is also rich in serotoninergic (5-HT) fibers which originate from the raphe nuclei and innervate the forebrain. In order to establish possible correlation(s) between the destruction of specific aminergic system(s) and some of the behavioral effects of VTA lesions, rat locomotor activities were recorded and DA, 5-HT and norepinephrine (NE) were estimated in discrete areas of the forebrain using specific and sensitive radioenzymatic methods.VTA lesions greatly affected DA and 5-HT levels in the forebrain but only induced minor effects on cortical NE.No significant correlations were found between the changes in locomotor activity and the reduction of 5-HT levels in the parietal and rhinal cortices, the striatum and the hippocampus.On the other hand, a very good correlation was observed between the increase in locomotor activity and the decrease in DA content in the frontal cortex (r= −0.82,n= 20, P < 0.01). Although not as striking, a correlation was also found between the changes in locomotor activity and those of DA levels in the nucleus accumbens, a structure innervated by the mesolimbic DA system (r= −0.47,n= 24, P < 0.05).A comparison between changes in DA levels in the frontal cortex and the nucleus accumbens after VTA lesions suggested that cell bodies of the mesocortical and mesolimbic DA systems, although very close, are not the same.It cannot be excluded that the mesolimbic DA system plays a role in the ‘VTA syndrome’. However, it is clear that the disappearance of DA in the frontal cortex is critical for the development of the non-vicarious locomotor hyperactivity. This suggests that the dopaminergic neurons which innervate the frontal cortex exert an inhibitory role on locomotor behavior.     

Midbrain dopaminergic neurons in the mouse: Computer-assisted mapping

The dopaminergic (DA) neurons in the midbrain play a role in cognition, affect and movement. The purpose of the present study was to map and quantify the number of DA neurons in the midbrain, within the nuclei that constitute cell groups A8, A9 and A10, in the mouse. Two strains of mice were used; the C57BL/6 strain was chosen because it is commonly used in neurobiological studies, and the FVB/N strain was chosen because it is used frequently in transgenic studies. DA neurons were identified, in every fifth 20-μm-thick coronal section, using an antibody against tyrosine hydroxylase. Cell locations were entered into a computer imaging system. The FVB/N strain has 42% more midbrain DA neurons than the C57BL/6 strain; on one side of the brain there were 15,135 ± 356 neurons (mean ± S.E.M.) in the FVB/N strain, and 10,645 ± 315 neurons in the C57BL/6 strain. In both strains, approximately 11% of the neurons were located in nucleus A8 (the DA neurons in the retrorubral field), 38% in nucleus A9 (the DA neurons in the substantia nigra pars compacta, pars reticulata, and pars lateralis), and 51% in nucleus A10 (the DA neurons in midline regions such as the ventral tegmental area, central linear nucleus, and interfascicular nucleus). The number of midbrain DA cells, and their distribution within the three nuclear groups, is discussed with respect to findings in other species. © 1996 Wiley-Liss, Inc.     

Antidromic identification of dopaminergic and other output neurons of the rat substantia nigra

In the present study dopamine (DA)-containing and other output neurons of the substantia nigra (SN) wer identified by antidromic stimulation from postulated target nuclei, the caudate-putamen, the thalamus, the cortex and the pontine reticular formation. To guide electrode placements, the topography of the nigrostriatal projection system was determined by retrograde tracing methods. Spontaneously active cells present in the SN were then classified in two groups according to the shape of their action potentials and their firing rate. Type I cells were located mainly in the pars compacta and could be antidromically-activated (AD-activated) from various locations along the course of the nigrostriatal pathway (caudate-putamen, globus pallidus, MFB) but not from other brain areas (ventromedial thalamus, motor cortex, pontine reticular formation). These neurons had a slow bursting pattern of firing, a very slow conduction velocity (0.58 m/sec), and a wide action potential. Their firing rate was dramatically reduced following the intravenous administration of apomorphine (ID 50: 9.3 microgram/kg), or the iontophoretic application of DA and GABA. Type II cells were located predominantly in the pars reticulata; most of them could be AD-activated from the ventromedial thalamus and the MFB but not from the motor cortex. A few of these cells could be AD-activated from the pontine reticular formation and the thalamus. A minority of type II cells, located in or near the pars compacta could be AD-activated from the caudate-putamen. In addition, their conduction velocuty was much higher (2.8 m/sec) and their firing rate far in excess of that exhibited by type I neurons. These neurons were inhibited by the iontophoretic application of GABA but not of DA. The microinjection of 6-hydroxydopamine (a neurotoxin relatively specific against catecholamine-containing neurons) in the vicinity of the MFB blocked selectively the propagation of antidromic spikes in type I but not type II cells. It is concluded that type I cells are the DA neurons of the nigrostriatal pathway. Type II cells are mainly oupput neurons that project to the ventromedial thalamus, the pons and the forebrain. This telencephalic projection most likely constitutes a second, non-DA, fast-conducting nigrostriatal pathway.     

Cholinergic modulation of midbrain dopaminergic systems

Dopamine neurons in the midbrain respond to behavioral events and environmental stimuli. Their different patterns of activation in turn modulate the activity of forebrain regions and modulate the expression of selective behavioral responses. However, their activity is closely dependent on the cholinergic systems in the brainstem. Ascending cholinergic projections from the pedunculopontine and laterodorsal tegmental nuclei target dopaminergic neurons in the substantia nigra compacta and ventral tegmental area following a topographical gradient. These projections, by means of the activation of acetylcholine receptors, influence the firing of dopamine neurons and therefore their responsiveness, ultimately affecting the release of dopamine in their forebrain targets. Brainstem cholinergic neurons are thus in a position to critically influence the activity of dopaminergic neurons in the midbrain, and thereby have a critical role in the expression of behavior.